dr_domi/udlbook
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity

Compare commits

base: dr_domi:v1.15
Branches Tags
dr_domi:main dr_domi:gh-pages
dr_domi:v5.0.3 dr_domi:v5.0.2 dr_domi:v5.0.1 dr_domi:v5.00 dr_domi:v4.0.4a dr_domi:v4.0.4 dr_domi:v.4.0.4 dr_domi:4.0.4 dr_domi:v4.0.3 dr_domi:v4.0.2 dr_domi:v4.0.1 dr_domi:v4.00 dr_domi:v2.06 dr_domi:v2.05 dr_domi:v2.04 dr_domi:v2.03 dr_domi:v2.0.2 dr_domi:v2.0.1 dr_domi:v2.00 dr_domi:v.1.20 dr_domi:v1.19 dr_domi:v.1.18 dr_domi:v1.17 dr_domi:v1.16 dr_domi:v1.15 dr_domi:v1.14 dr_domi:v1.1.3 dr_domi:v1.1.2 dr_domi:v1.1.1 dr_domi:v1.1 dr_domi:v1.0.4 dr_domi:v1.0.3 dr_domi:v1.02 dr_domi:v1.0.1 dr_domi:v1.0.0 dr_domi:v0.7.14 dr_domi:v0.7.13 dr_domi:v0.7.12 dr_domi:v.0.7.12 dr_domi:v0.7.11 dr_domi:v0.7.10 dr_domi:v0.7.9 dr_domi:v0.7.8 dr_domi:v0.7.7 dr_domi:v0.7.6 dr_domi:v0.7.5 dr_domi:v0.7.4 dr_domi:v0.7.3 dr_domi:v0.7.2 dr_domi:v0.7.1 dr_domi:v0.7.0 dr_domi:v0.6.1 dr_domi:v0.6.0 dr_domi:v0.5.2 dr_domi:v.0.5.1 dr_domi:v0.5.0 dr_domi:v0.4.0 dr_domi:v0.3.1 dr_domi:v0.3.0 dr_domi:v0.2.1 dr_domi:v0.2.0 dr_domi:v0.1.0
...
compare: dr_domi:v.1.18
Branches Tags
dr_domi:main dr_domi:gh-pages
dr_domi:v5.0.3 dr_domi:v5.0.2 dr_domi:v5.0.1 dr_domi:v5.00 dr_domi:v4.0.4a dr_domi:v4.0.4 dr_domi:v.4.0.4 dr_domi:4.0.4 dr_domi:v4.0.3 dr_domi:v4.0.2 dr_domi:v4.0.1 dr_domi:v4.00 dr_domi:v2.06 dr_domi:v2.05 dr_domi:v2.04 dr_domi:v2.03 dr_domi:v2.0.2 dr_domi:v2.0.1 dr_domi:v2.00 dr_domi:v.1.20 dr_domi:v1.19 dr_domi:v.1.18 dr_domi:v1.17 dr_domi:v1.16 dr_domi:v1.15 dr_domi:v1.14 dr_domi:v1.1.3 dr_domi:v1.1.2 dr_domi:v1.1.1 dr_domi:v1.1 dr_domi:v1.0.4 dr_domi:v1.0.3 dr_domi:v1.02 dr_domi:v1.0.1 dr_domi:v1.0.0 dr_domi:v0.7.14 dr_domi:v0.7.13 dr_domi:v0.7.12 dr_domi:v.0.7.12 dr_domi:v0.7.11 dr_domi:v0.7.10 dr_domi:v0.7.9 dr_domi:v0.7.8 dr_domi:v0.7.7 dr_domi:v0.7.6 dr_domi:v0.7.5 dr_domi:v0.7.4 dr_domi:v0.7.3 dr_domi:v0.7.2 dr_domi:v0.7.1 dr_domi:v0.7.0 dr_domi:v0.6.1 dr_domi:v0.6.0 dr_domi:v0.5.2 dr_domi:v.0.5.1 dr_domi:v0.5.0 dr_domi:v0.4.0 dr_domi:v0.3.1 dr_domi:v0.3.0 dr_domi:v0.2.1 dr_domi:v0.2.0 dr_domi:v0.1.0

175 Commits
v1.15 ... v.1.18

Author SHA1 Message Date
udlbook
ea1a7aeba0 Add files via upload 2023-12-24 13:38:05 -05:00
udlbook
d6d0afdfd3 Created using Colaboratory 2023-12-24 12:34:48 -05:00
udlbook
56b4edb871 Created using Colaboratory 2023-12-24 12:01:00 -05:00
udlbook
86387e2901 Created using Colaboratory 2023-12-24 11:53:10 -05:00
udlbook
b9ec83d5f5 Created using Colaboratory 2023-12-24 11:49:04 -05:00
udlbook
0748270a1c Created using Colaboratory 2023-12-24 11:42:23 -05:00
udlbook
51c582f693 Update 6_2_Gradient_Descent.ipynb 2023-12-24 11:36:07 -05:00
udlbook
d7ca8b80d4 Update 3_1_Shallow_Networks_I.ipynb 2023-12-24 11:16:55 -05:00
udlbook
7549cbaa59 Update 5_1_Least_Squares_Loss.ipynb 2023-12-24 10:18:32 -05:00
udlbook
3cdb675cef Created using Colaboratory 2023-12-24 10:16:00 -05:00
udlbook
48d9a4e108 Created using Colaboratory 2023-12-24 10:13:36 -05:00
udlbook
73c58fa0fa Created using Colaboratory 2023-12-24 10:12:00 -05:00
udlbook
dbde6d3d89 Created using Colaboratory 2023-12-24 10:03:28 -05:00
udlbook
182293e8d6 Update 6_3_Stochastic_Gradient_Descent.ipynb 2023-12-24 09:19:51 -05:00
udlbook
d7468ee1c1 Add files via upload 2023-12-23 11:16:28 -05:00
udlbook
5abe61e767 Add files via upload 2023-12-23 11:05:04 -05:00
udlbook
476335cc6f Update 13_2_Graph_Classification.ipynb 2023-12-20 15:31:06 -05:00
udlbook
337d6cd544 Update 13_3_Neighborhood_Sampling.ipynb 2023-12-20 15:30:40 -05:00
udlbook
76498f8ef9 Created using Colaboratory 2023-12-20 15:29:10 -05:00
udlbook
89744c0f0f Update 10_1_1D_Convolution.ipynb 2023-12-20 15:27:59 -05:00
udlbook
ec40d10ecd Update 21_1_Bias_Mitigation.ipynb 2023-12-20 15:26:48 -05:00
udlbook
a71283e322 Update 18_1_Diffusion_Encoder.ipynb 2023-12-20 15:24:15 -05:00
udlbook
d9e7306ef4 Update 19_1_Markov_Decision_Processes.ipynb 2023-12-20 15:23:18 -05:00
udlbook
d5304c8034 Created using Colaboratory 2023-12-20 15:22:17 -05:00
udlbook
985c08950e Update 2_1_Supervised_Learning.ipynb 2023-12-20 15:19:07 -05:00
udlbook
97d738d408 Update 13_2_Graph_Classification.ipynb 2023-12-20 14:43:21 -05:00
udlbook
7e264f5310 Created using Colaboratory 2023-12-20 14:38:30 -05:00
udlbook
3b266ba33b Created using Colaboratory 2023-12-20 14:17:47 -05:00
udlbook
f75b1cb983 Created using Colaboratory 2023-12-20 14:15:24 -05:00
udlbook
7afe033e50 Update 4_3_Deep_Networks.ipynb 2023-12-18 16:55:51 -05:00
udlbook
c68045feb1 Update index.html 2023-12-17 17:58:48 -05:00
udlbook
73fb6a2988 Add files via upload 2023-12-17 17:56:56 -05:00
udlbook
aa04c283e8 Update 5_1_Least_Squares_Loss.ipynb 2023-12-17 17:49:34 -05:00
udlbook
c56251df11 Update 3_3_Shallow_Network_Regions.ipynb 2023-12-17 17:27:23 -05:00
udlbook
fa7005b29a Merge pull request #109 from yrahal/main 
Typo fixes in Notebooks/Chap03/3_3_Shallow_Network_Regions.ipynb
 2023-12-17 17:22:27 -05:00
udlbook
2e343bc652 Created using Colaboratory 2023-12-17 20:30:17 +00:00
udlbook
905d7d1ac4 Created using Colaboratory 2023-12-14 18:35:49 +00:00
udlbook
5f8f05a381 Delete Notebooks/Chap12/12_1_Self_Attention_A.ipynb 2023-12-14 17:36:45 +00:00
Youcef Rahal
2eb8eebf70 Typo fixes 2023-12-13 19:58:52 -05:00
udlbook
73c3fcc40b Update index.html 2023-12-12 19:56:53 +00:00
udlbook
aa9c613167 Update index.html 2023-12-12 19:35:28 +00:00
udlbook
2ec1f42a80 Update index.html 2023-12-12 19:31:30 +00:00
udlbook
e399f14a82 Created using Colaboratory 2023-12-12 11:01:07 +00:00
udlbook
96049aabcb Created using Colaboratory 2023-12-10 17:23:26 +00:00
udlbook
912cc890df Created using Colaboratory 2023-12-10 17:19:43 +00:00
udlbook
88501605df Merge pull request #104 from tonyjo/main 
changed to ax.set_title(title) so title appears on plots
 2023-12-10 17:11:55 +00:00
udlbook
16ef8a7333 Merge branch 'main' into main 2023-12-10 17:11:38 +00:00
udlbook
aacf54fb8b Created using Colaboratory 2023-12-10 17:07:58 +00:00
udlbook
40fc192198 Created using Colaboratory 2023-12-10 17:06:17 +00:00
udlbook
de1e19ace9 Delete 18_1_Diffusion_Encoder.ipynb 2023-12-10 17:05:32 +00:00
udlbook
5e701faf90 Created using Colaboratory 2023-12-10 17:05:17 +00:00
udlbook
edc78dc659 Merge pull request #108 from ani0075saha/main 
Fix math.comb() typo
 2023-12-10 14:43:54 +00:00
udlbook
5300392d66 Merge pull request #107 from yrahal/main 
Fixes 0.1/0.01 comment/code granularity mismatch in Notebooks/Chap01/1_1_BackgroundMathematics.ipynb
 2023-12-10 14:42:49 +00:00
Youcef Rahal
4696eee641 Notebook 3.2: Fixes missing mention of phi_13, phi_23 2023-12-10 09:32:55 -05:00
udlbook
3258300849 Created using Colaboratory 2023-12-07 19:15:25 +00:00
udlbook
5ba36dd1e8 Created using Colaboratory 2023-12-07 18:07:12 +00:00
udlbook
d7750430f7 Created using Colaboratory 2023-12-07 17:29:53 +00:00
udlbook
e184e09b28 Created using Colaboratory 2023-12-07 17:01:48 +00:00
udlbook
6cfd494ed8 Update index.html 2023-12-05 08:45:29 +00:00
udlbook
986b51bdbd Add files via upload 2023-12-05 08:41:36 +00:00
Aniruddha Saha
9a9321d923 Fix math.comb() typo 2023-12-04 20:57:31 -05:00
Youcef Rahal
714c58bbf3 Fixes 0.1/0.01 comment/code granularity mismatch in Notebooks/Chap01/1_1_BackgroundMathematics.ipynb 2023-12-04 06:20:47 -05:00
udlbook
a8ea2b429f Merge pull request #100 from pitmonticone/main 
Fix typos in notebooks
 2023-11-30 17:07:23 +00:00
Pietro Monticone
fefef63df4 Update CM20315_Transformers.ipynb 2023-11-30 16:46:38 +01:00
Pietro Monticone
193e2329f2 Update CM20315_Training_III.ipynb 2023-11-30 16:45:28 +01:00
Pietro Monticone
9b13823ca8 Update CM20315_Training_II.ipynb 2023-11-30 16:44:42 +01:00
Pietro Monticone
685d910bbc Update CM20315_Training_I.ipynb 2023-11-30 16:44:01 +01:00
Pietro Monticone
4429600bcc Update CM20315_Shallow.ipynb 2023-11-30 16:43:27 +01:00
Pietro Monticone
6b76bbc7c3 Update CM20315_Loss.ipynb 2023-11-30 16:42:27 +01:00
Pietro Monticone
a5d98bb379 Update CM20315_Loss_III.ipynb 2023-11-30 16:40:52 +01:00
Pietro Monticone
428ca727db Update CM20315_Loss_II.ipynb 2023-11-30 16:39:42 +01:00
Pietro Monticone
6c8411ae1c Update CM20315_Intro.ipynb 2023-11-30 16:38:17 +01:00
Pietro Monticone
c951720282 Update CM20315_Intro_Answers.ipynb 2023-11-30 16:37:46 +01:00
Pietro Monticone
79578aa4a1 Update CM20315_Gradients_III.ipynb 2023-11-30 16:37:12 +01:00
Pietro Monticone
6b2f25101e Update CM20315_Gradients_II.ipynb 2023-11-30 16:36:35 +01:00
Pietro Monticone
ef28d848df Update CM20315_Convolution_III.ipynb 2023-11-30 16:33:59 +01:00
Pietro Monticone
e03fad482b Update CM20315_Convolution_II.ipynb 2023-11-30 16:33:04 +01:00
Pietro Monticone
4fc1abc20e Merge branch 'udlbook:main' into main 2023-11-30 16:20:32 +01:00
tonyjo
aea371dc7d changed to ax.set_title(title) so title appears on plots 2023-11-29 13:45:30 -05:00
udlbook
36d2695a41 Created using Colaboratory 2023-11-29 09:36:54 +00:00
udlbook
7a5113de21 Update index.html 2023-11-27 20:35:29 +00:00
udlbook
bf7f511ee9 Created using Colaboratory 2023-11-26 19:00:46 +00:00
Pietro Monticone
a7af9f559e Update 1_1_BackgroundMathematics.ipynb 2023-11-26 11:18:22 +01:00
Pietro Monticone
866861a06c Merge branch 'udlbook:main' into main 2023-11-26 11:15:50 +01:00
udlbook
2cfbcafedc Created using Colaboratory 2023-11-25 17:02:46 +00:00
udlbook
58a150843f Created using Colaboratory 2023-11-25 17:01:43 +00:00
Pietro Monticone
ffe7ffc823 Update 12_1_Self_Attention.ipynb 2023-11-24 11:21:47 +01:00
Pietro Monticone
da3a5ad2e9 Update 21_2_Explainability.ipynb 2023-11-24 11:18:22 +01:00
Pietro Monticone
8411fdd1d2 Update 21_1_Bias_Mitigation.ipynb 2023-11-24 11:18:20 +01:00
udlbook
362d8838e8 Update index.html 2023-11-24 09:53:55 +00:00
udlbook
718cfba4dc Update index.html 2023-11-24 09:47:01 +00:00
udlbook
41d99cf6d3 Created using Colaboratory 2023-11-24 09:01:15 +00:00
udlbook
5c10091b48 Created using Colaboratory 2023-11-23 11:08:41 +00:00
udlbook
b47c4a210a Created using Colaboratory 2023-11-20 21:05:39 +00:00
udlbook
cef074a42b Created using Colaboratory 2023-11-20 16:06:11 +00:00
udlbook
6a8a1092c3 Created using Colaboratory 2023-11-20 15:18:32 +00:00
udlbook
c42f92d6a3 Created using Colaboratory 2023-11-20 15:15:35 +00:00
udlbook
dc87aa07c3 Created using Colaboratory 2023-11-20 14:50:18 +00:00
udlbook
b50b343096 Created using Colaboratory 2023-11-20 14:47:31 +00:00
udlbook
2056594cdd Created using Colaboratory 2023-11-20 14:46:26 +00:00
udlbook
73cf5ff7da Add files via upload 2023-11-15 18:50:13 +00:00
udlbook
a529c94875 Add files via upload 2023-11-15 18:41:18 +00:00
udlbook
07fd109b1f Delete CM20315/Data/val_data_y.npy 2023-11-15 18:40:43 +00:00
udlbook
57a6582798 Delete CM20315/Data/train_data_y.npy 2023-11-15 18:40:33 +00:00
udlbook
55ab79fcf8 Delete CM20315/Data/val_data_x.npy 2023-11-15 18:40:17 +00:00
udlbook
b2d5116140 Delete CM20315/Data/train_data_x.npy 2023-11-15 18:40:06 +00:00
udlbook
87632b5081 Add files via upload 2023-11-15 18:22:25 +00:00
udlbook
845cac5229 Delete CM20315/Data/val_data_y.npy 2023-11-15 18:16:35 +00:00
udlbook
71229805b4 Delete CM20315/Data/val_data_x.npy 2023-11-15 18:16:25 +00:00
udlbook
b06a37349f Delete CM20315/Data/train_data_y.npy 2023-11-15 18:16:14 +00:00
udlbook
164a5dc979 Delete CM20315/Data/train_data_x.npy 2023-11-15 18:16:04 +00:00
udlbook
5e9cc7243d New data files 2023-11-15 18:07:20 +00:00
udlbook
b09262f4ad Delete CM20315/Data/val_data_y.npy 2023-11-15 18:07:02 +00:00
udlbook
058d116638 Delete CM20315/Data/val_data_x.npy 2023-11-15 18:06:46 +00:00
udlbook
4a5e2cf87c Delete CM20315/Data/train_data_y.npy 2023-11-15 18:06:34 +00:00
udlbook
cdeef5f9f7 Delete CM20315/Data/train_data_x.npy 2023-11-15 18:06:23 +00:00
udlbook
79c6bc669b New train test files 2023-11-15 18:05:04 +00:00
udlbook
ed9f9ae8c8 Add files via upload 2023-11-15 18:04:31 +00:00
udlbook
26511a078e Delete CM20315/Data/test_data_y.npy 2023-11-14 19:09:00 +00:00
udlbook
2a53370576 Delete CM20315/Data/test_data_x.npy 2023-11-14 19:08:45 +00:00
udlbook
5b009deabb Created using Colaboratory 2023-11-14 16:41:46 +00:00
udlbook
aaa1343359 Created using Colaboratory 2023-11-14 16:13:06 +00:00
udlbook
259f34e985 Created using Colaboratory 2023-11-14 11:42:12 +00:00
udlbook
f63ddc7313 Created using Colaboratory 2023-11-14 10:34:50 +00:00
udlbook
00d180bf88 Update index.html 2023-11-14 09:41:53 +00:00
udlbook
ecd377e775 Update index.html 2023-11-14 09:15:41 +00:00
udlbook
35bbac271b Update index.html 2023-11-14 09:09:49 +00:00
udlbook
96eeed8194 Created using Colaboratory 2023-11-14 08:58:30 +00:00
udlbook
d58115baaa Delete Notebooks/Chapter21/21_1_Bias_Mitigation.ipynb 2023-11-14 08:57:47 +00:00
udlbook
ae67af61a8 Update index.html 2023-11-14 08:57:01 +00:00
udlbook
fe9fd3da8b Created using Colaboratory 2023-11-13 21:29:35 +00:00
udlbook
b9238e35dc Created using Colaboratory 2023-11-13 21:27:38 +00:00
udlbook
34235a319c Created using Colaboratory 2023-11-06 13:11:13 +00:00
udlbook
0c5aacbd8b Created using Colaboratory 2023-11-06 13:10:09 +00:00
udlbook
7a07cba349 Merge pull request #96 from pitmonticone/main 
Fix typos in notebooks
 2023-11-02 16:43:34 +00:00
udlbook
110de1488b Created using Colaboratory 2023-10-31 12:01:20 +00:00
Pietro Monticone
8fa8efa9dd Update 19_5_Control_Variates.ipynb 2023-10-30 18:20:33 +01:00
Pietro Monticone
d48eeab4a4 Update 19_4_Temporal_Difference_Methods.ipynb 2023-10-30 18:20:02 +01:00
Pietro Monticone
f855263f9f Update 18_2_1D_Diffusion_Model.ipynb 2023-10-30 18:17:44 +01:00
Pietro Monticone
aa5c7f77d6 Update 18_1_Diffusion_Encoder.ipynb 2023-10-30 18:17:14 +01:00
Pietro Monticone
5cbdaefc96 Update 17_2_Reparameterization_Trick.ipynb 2023-10-30 18:15:51 +01:00
Pietro Monticone
78eaa6312d Update 16_2_Autoregressive_Flows.ipynb 2023-10-30 18:15:48 +01:00
Pietro Monticone
be98b4df14 Update 15_2_Wasserstein_Distance.ipynb 2023-10-30 18:12:54 +01:00
Pietro Monticone
7793b9c553 Update 15_1_GAN_Toy_Example.ipynb 2023-10-30 18:12:09 +01:00
Pietro Monticone
01f3eb30be Update 12_2_Multihead_Self_Attention.ipynb 2023-10-30 18:09:40 +01:00
Pietro Monticone
ecbe2f1051 Update 12_1_Self_Attention.ipynb 2023-10-30 18:08:36 +01:00
Pietro Monticone
4f2d3f31f0 Update 9_4_Bayesian_Approach.ipynb 2023-10-30 18:04:23 +01:00
Pietro Monticone
94df10a9ec Update 9_1_L2_Regularization.ipynb 2023-10-30 18:00:44 +01:00
Pietro Monticone
cd76e76ad2 Update 8_2_Bias_Variance_Trade_Off.ipynb 2023-10-30 17:59:24 +01:00
Pietro Monticone
008b058b14 Merge branch 'main' of https://github.com/pitmonticone/udlbook 2023-10-30 17:57:40 +01:00
Pietro Monticone
f57925947d Update 7_2_Backpropagation.ipynb 2023-10-30 17:57:39 +01:00
Pietro Monticone
b69e7bf696 Merge branch 'udlbook:main' into main 2023-10-30 17:53:42 +01:00
Pietro Monticone
21fe352e75 Update 6_5_Adam.ipynb 2023-10-30 17:52:35 +01:00
Pietro Monticone
e9349b415f Update 6_4_Momentum.ipynb 2023-10-30 17:52:32 +01:00
Pietro Monticone
e412e965ca Update 6_3_Stochastic_Gradient_Descent.ipynb 2023-10-30 17:52:29 +01:00
Pietro Monticone
d60b92b608 Update 6_2_Gradient_Descent.ipynb 2023-10-30 17:52:25 +01:00
udlbook
9266025bdd Created using Colaboratory 2023-10-30 16:28:04 +00:00
Pietro Monticone
594497ee4c Update 5_1_Least_Squares_Loss.ipynb 2023-10-30 17:04:35 +01:00
Pietro Monticone
6eb5986784 Update 2_1_Supervised_Learning.ipynb 2023-10-30 17:01:44 +01:00
udlbook
8c2e3f71e8 Update index.html 2023-10-30 10:50:52 +00:00
udlbook
fbf9ac0e40 Created using Colaboratory 2023-10-30 09:26:06 +00:00
udlbook
fd1844ed44 Created using Colaboratory 2023-10-26 17:51:07 +01:00
udlbook
4d0825ef42 Created using Colaboratory 2023-10-26 17:32:25 +01:00
udlbook
5db114e492 Created using Colaboratory 2023-10-26 17:19:04 +01:00
udlbook
7d9296c157 Created using Colaboratory 2023-10-25 15:59:58 +01:00
udlbook
66016f8dea Created using Colaboratory 2023-10-25 15:35:28 +01:00
udlbook
b3f8533864 Created using Colaboratory 2023-10-25 15:08:28 +01:00
udlbook
2ca7ddb6d9 Created using Colaboratory 2023-10-25 10:23:10 +01:00
udlbook
452edf3a1f Created using Colaboratory 2023-10-24 17:59:40 +01:00
udlbook
78851c3da2 Created using Colaboratory 2023-10-24 13:37:38 +01:00
udlbook
df8829934e Created using Colaboratory 2023-10-24 13:18:55 +01:00
udlbook
fba121b30b Created using Colaboratory 2023-10-24 13:16:34 +01:00
udlbook
33a94fb59f Created using Colaboratory 2023-10-24 13:10:47 +01:00
udlbook
0af1ea979c Update index.html 2023-10-24 08:11:59 +01:00
udlbook
3b171383d5 Update index.html 2023-10-23 17:07:38 +01:00
79 changed files with 4438 additions and 775 deletions
Expand all files Collapse all files

4
CM20315/CM20315_Convolution_II.ipynb
View File

@@ -105,7 +105,7 @@
"cell_type": "code",
"source": [
"\n",
"# TODO Create a model with the folowing layers\n",
"# TODO Create a model with the following layers\n",
"# 1. Convolutional layer, (input=length 40 and 1 channel, kernel size 3x3, stride 2, padding=\"valid\", 15 output channels ) \n",
"# 2. ReLU\n",
"# 3. Convolutional layer, (input=length 19 and 15 channels, kernel size 3x3, stride 2, padding=\"valid\", 15 output channels )\n",
@@ -120,7 +120,7 @@
"# https://pytorch.org/docs/1.13/generated/torch.nn.Linear.html?highlight=linear#torch.nn.Linear\n",
"\n",
"# Replace the following function which just runs a standard fully connected network\n",
"# The flatten at the beginning is becuase we are passing in the data in a slightly different format.\n",
"# The flatten at the beginning is because we are passing in the data in a slightly different format.\n",
"model = nn.Sequential(\n",
"nn.Flatten(),\n",
"nn.Linear(40, 100),\n",

2
CM20315/CM20315_Convolution_III.ipynb
View File

@@ -148,7 +148,7 @@
"# 8. A flattening operation\n",
"# 9. A fully connected layer mapping from (whatever dimensions we are at-- find out using .shape) to 50 \n",
"# 10. A ReLU\n",
"# 11. A fully connected layer mappiing from 50 to 10 dimensions\n",
"# 11. A fully connected layer mapping from 50 to 10 dimensions\n",
"# 12. A softmax function.\n",
"\n",
"# Replace this class which implements a minimal network (which still does okay)\n",

6
CM20315/CM20315_Gradients_II.ipynb
View File

@@ -32,7 +32,7 @@
"source": [
"# Gradients II: Backpropagation algorithm\n",
"\n",
"In this practical, we'll investigate the backpropagation algoritithm. This computes the gradients of the loss with respect to all of the parameters (weights and biases) in the network. We'll use these gradients when we run stochastic gradient descent."
"In this practical, we'll investigate the backpropagation algorithm. This computes the gradients of the loss with respect to all of the parameters (weights and biases) in the network. We'll use these gradients when we run stochastic gradient descent."
],
"metadata": {
"id": "L6chybAVFJW2"
@@ -53,7 +53,7 @@
{
"cell_type": "markdown",
"source": [
"First let's define a neural network. We'll just choose the weights and biaes randomly for now"
"First let's define a neural network. We'll just choose the weights and biases randomly for now"
],
"metadata": {
"id": "nnUoI0m6GyjC"
@@ -178,7 +178,7 @@
{
"cell_type": "markdown",
"source": [
"Now let's define a loss function. We'll just use the least squaures loss function. We'll also write a function to compute dloss_doutpu"
"Now let's define a loss function. We'll just use the least squares loss function. We'll also write a function to compute dloss_doutpu"
],
"metadata": {
"id": "SxVTKp3IcoBF"

4
CM20315/CM20315_Gradients_III.ipynb
View File

@@ -53,7 +53,7 @@
{
"cell_type": "markdown",
"source": [
"First let's define a neural network. We'll just choose the weights and biaes randomly for now"
"First let's define a neural network. We'll just choose the weights and biases randomly for now"
],
"metadata": {
"id": "nnUoI0m6GyjC"
@@ -204,7 +204,7 @@
{
"cell_type": "markdown",
"source": [
"Now let's define a loss function. We'll just use the least squaures loss function. We'll also write a function to compute dloss_doutput\n"
"Now let's define a loss function. We'll just use the least squares loss function. We'll also write a function to compute dloss_doutput\n"
],
"metadata": {
"id": "SxVTKp3IcoBF"

2
CM20315/CM20315_Intro.ipynb
View File

@@ -176,7 +176,7 @@
"# Color represents y value (brighter = higher value)\n",
"# Black = -10 or less, White = +10 or more\n",
"# 0 = mid orange\n",
"# Lines are conoturs where value is equal\n",
"# Lines are contours where value is equal\n",
"draw_2D_function(x1,x2,y)\n",
"\n",
"# TODO\n",

2
CM20315/CM20315_Intro_Answers.ipynb
View File

@@ -215,7 +215,7 @@
"# Color represents y value (brighter = higher value)\n",
"# Black = -10 or less, White = +10 or more\n",
"# 0 = mid orange\n",
"# Lines are conoturs where value is equal\n",
"# Lines are contours where value is equal\n",
"draw_2D_function(x1,x2,y)\n",
"\n",
"# TODO\n",

14
CM20315/CM20315_Loss.ipynb
View File

@@ -36,7 +36,7 @@
"\n",
"We'll compute loss functions for maximum likelihood, minimum negative log likelihood, and least squares and show that they all imply that we should use the same parameter values\n",
"\n",
"In part II, we'll investigate binary classification (where the output data is 0 or 1). This will be based on the Bernouilli distribution\n",
"In part II, we'll investigate binary classification (where the output data is 0 or 1). This will be based on the Bernoulli distribution\n",
"\n",
"In part III we'll investigate multiclass classification (where the output data is 0,1, or, 2). This will be based on the categorical distribution."
],
@@ -178,7 +178,7 @@
{
"cell_type": "markdown",
"source": [
"The blue line i sthe mean prediction of the model and the gray area represents plus/minus two standardard deviations. This model fits okay, but could be improved. Let's compute the loss. We'll compute the the least squares error, the likelihood, the negative log likelihood."
"The blue line is the mean prediction of the model and the gray area represents plus/minus two standard deviations. This model fits okay, but could be improved. Let's compute the loss. We'll compute the the least squares error, the likelihood, the negative log likelihood."
],
"metadata": {
"id": "MvVX6tl9AEXF"
@@ -276,7 +276,7 @@
"beta_0, omega_0, beta_1, omega_1 = get_parameters()\n",
"# Use our neural network to predict the mean of the Gaussian\n",
"mu_pred = shallow_nn(x_train, beta_0, omega_0, beta_1, omega_1)\n",
"# Set the standard devation to something reasonable\n",
"# Set the standard deviation to something reasonable\n",
"sigma = 0.2\n",
"# Compute the likelihood\n",
"likelihood = compute_likelihood(y_train, mu_pred, sigma)\n",
@@ -292,7 +292,7 @@
{
"cell_type": "markdown",
"source": [
"You can see that this gives a very small answer, even for this small 1D dataset, and with the model fitting quite well. This is because it is the product of sveral probabilities, which are all quite small themselves.\n",
"You can see that this gives a very small answer, even for this small 1D dataset, and with the model fitting quite well. This is because it is the product of several probabilities, which are all quite small themselves.\n",
"This will get out of hand pretty quickly with real datasets -- the likelihood will get so small that we can't represent it with normal finite-precision math\n",
"\n",
"This is why we use negative log likelihood"
@@ -326,7 +326,7 @@
"beta_0, omega_0, beta_1, omega_1 = get_parameters()\n",
"# Use our neural network to predict the mean of the Gaussian\n",
"mu_pred = shallow_nn(x_train, beta_0, omega_0, beta_1, omega_1)\n",
"# Set the standard devation to something reasonable\n",
"# Set the standard deviation to something reasonable\n",
"sigma = 0.2\n",
"# Compute the log likelihood\n",
"nll = compute_negative_log_likelihood(y_train, mu_pred, sigma)\n",
@@ -397,7 +397,7 @@
"source": [
"# Define a range of values for the parameter\n",
"beta_1_vals = np.arange(0,1.0,0.01)\n",
"# Create some arrays to store the likelihoods, negative log likehoos and sum of squares\n",
"# Create some arrays to store the likelihoods, negative log likelihoods and sum of squares\n",
"likelihoods = np.zeros_like(beta_1_vals)\n",
"nlls = np.zeros_like(beta_1_vals)\n",
"sum_squares = np.zeros_like(beta_1_vals)\n",
@@ -482,7 +482,7 @@
"source": [
"# Define a range of values for the parameter\n",
"sigma_vals = np.arange(0.1,0.5,0.005)\n",
"# Create some arrays to store the likelihoods, negative log likehoos and sum of squares\n",
"# Create some arrays to store the likelihoods, negative log likelihoods and sum of squares\n",
"likelihoods = np.zeros_like(sigma_vals)\n",
"nlls = np.zeros_like(sigma_vals)\n",
"sum_squares = np.zeros_like(sigma_vals)\n",

14
CM20315/CM20315_Loss_II.ipynb
View File

@@ -34,7 +34,7 @@
"\n",
"This practical investigates loss functions. In part I we investigated univariate regression (where the output data $y$ is continuous. Our formulation was based on the normal/Gaussian distribution.\n",
"\n",
"In this notebook, we investigate binary classification (where the output data is 0 or 1). This will be based on the Bernouilli distribution\n",
"In this notebook, we investigate binary classification (where the output data is 0 or 1). This will be based on the Bernoulli distribution\n",
"\n",
"In part III we'll investigate multiclass classification (where the outputs data can take multiple values 1,... K.\n",
"\n",
@@ -199,7 +199,7 @@
{
"cell_type": "markdown",
"source": [
"The left is model output and the right is the model output after the sigmoid has been applied, so it now lies in the range [0,1] and represents the probabiilty, that y=1. The black dots show the training data. We'll compute the the likelihood and the negative log likelihood."
"The left is model output and the right is the model output after the sigmoid has been applied, so it now lies in the range [0,1] and represents the probability, that y=1. The black dots show the training data. We'll compute the the likelihood and the negative log likelihood."
],
"metadata": {
"id": "MvVX6tl9AEXF"
@@ -210,7 +210,7 @@
"source": [
"# Return probability under Bernoulli distribution for input x\n",
"def bernoulli_distribution(y, lambda_param):\n",
" # TODO-- write in the equation for the Bernoullid distribution \n",
" # TODO-- write in the equation for the Bernoulli distribution \n",
" # Equation 5.17 from the notes (you will need np.power)\n",
" # Replace the line below\n",
" prob = np.zeros_like(y)\n",
@@ -249,7 +249,7 @@
"source": [
"# Return the likelihood of all of the data under the model\n",
"def compute_likelihood(y_train, lambda_param):\n",
" # TODO -- compute the likelihood of the data -- the product of the Bernoullis probabilities for each data point\n",
" # TODO -- compute the likelihood of the data -- the product of the Bernoulli's probabilities for each data point\n",
" # Top line of equation 5.3 in the notes\n",
" # You will need np.prod() and the bernoulli_distribution function you used above\n",
" # Replace the line below\n",
@@ -284,7 +284,7 @@
{
"cell_type": "markdown",
"source": [
"You can see that this gives a very small answer, even for this small 1D dataset, and with the model fitting quite well. This is because it is the product of sveral probabilities, which are all quite small themselves.\n",
"You can see that this gives a very small answer, even for this small 1D dataset, and with the model fitting quite well. This is because it is the product of several probabilities, which are all quite small themselves.\n",
"This will get out of hand pretty quickly with real datasets -- the likelihood will get so small that we can't represent it with normal finite-precision math\n",
"\n",
"This is why we use negative log likelihood"
@@ -317,7 +317,7 @@
"beta_0, omega_0, beta_1, omega_1 = get_parameters()\n",
"# Use our neural network to predict the mean of the Gaussian\n",
"model_out = shallow_nn(x_train, beta_0, omega_0, beta_1, omega_1)\n",
"# Set the standard devation to something reasonable\n",
"# Set the standard deviation to something reasonable\n",
"lambda_train = sigmoid(model_out)\n",
"# Compute the log likelihood\n",
"nll = compute_negative_log_likelihood(y_train, lambda_train)\n",
@@ -362,7 +362,7 @@
"source": [
"# Define a range of values for the parameter\n",
"beta_1_vals = np.arange(-2,6.0,0.1)\n",
"# Create some arrays to store the likelihoods, negative log likehoods\n",
"# Create some arrays to store the likelihoods, negative log likelihoods\n",
"likelihoods = np.zeros_like(beta_1_vals)\n",
"nlls = np.zeros_like(beta_1_vals)\n",
"\n",

12
CM20315/CM20315_Loss_III.ipynb
View File

@@ -33,7 +33,7 @@
"# Loss functions part III\n",
"\n",
"This practical investigates loss functions. In part I we investigated univariate regression (where the output data $y$ is continuous. Our formulation was based on the normal/Gaussian distribution.\n",
"In part II we investigated binary classification (where the output data is 0 or 1). This will be based on the Bernouilli distribution.<br><br>\n",
"In part II we investigated binary classification (where the output data is 0 or 1). This will be based on the Bernoulli distribution.<br><br>\n",
"\n",
"Now we'll investigate multiclass classification (where the outputs data can take multiple values 1,... K, which is based on the categorical distribution\n",
"\n",
@@ -218,7 +218,7 @@
{
"cell_type": "markdown",
"source": [
"The left is model output and the right is the model output after the softmax has been applied, so it now lies in the range [0,1] and represents the probabiilty, that y=0 (red), 1 (green) and 2 (blue) The dots at the bottom show the training data with the same color scheme. So we want the red curve to be high where there are red dots, the green curve to be high where there are green dotsmand the blue curve to be high where there are blue dots We'll compute the the likelihood and the negative log likelihood."
"The left is model output and the right is the model output after the softmax has been applied, so it now lies in the range [0,1] and represents the probability, that y=0 (red), 1 (green) and 2 (blue) The dots at the bottom show the training data with the same color scheme. So we want the red curve to be high where there are red dots, the green curve to be high where there are green dotsmand the blue curve to be high where there are blue dots We'll compute the the likelihood and the negative log likelihood."
],
"metadata": {
"id": "MvVX6tl9AEXF"
@@ -228,7 +228,7 @@
"cell_type": "code",
"source": [
"# Return probability under Bernoulli distribution for input x\n",
"# Complicated code to commpute it but just take value from row k of lambda param where y =k, \n",
"# Complicated code to compute it but just take value from row k of lambda param where y =k, \n",
"def categorical_distribution(y, lambda_param):\n",
" prob = np.zeros_like(y)\n",
" for row_index in range(lambda_param.shape[0]):\n",
@@ -305,7 +305,7 @@
{
"cell_type": "markdown",
"source": [
"You can see that this gives a very small answer, even for this small 1D dataset, and with the model fitting quite well. This is because it is the product of sveral probabilities, which are all quite small themselves.\n",
"You can see that this gives a very small answer, even for this small 1D dataset, and with the model fitting quite well. This is because it is the product of several probabilities, which are all quite small themselves.\n",
"This will get out of hand pretty quickly with real datasets -- the likelihood will get so small that we can't represent it with normal finite-precision math\n",
"\n",
"This is why we use negative log likelihood"
@@ -338,7 +338,7 @@
"beta_0, omega_0, beta_1, omega_1 = get_parameters()\n",
"# Use our neural network to predict the mean of the Gaussian\n",
"model_out = shallow_nn(x_train, beta_0, omega_0, beta_1, omega_1)\n",
"# Set the standard devation to something reasonable\n",
"# Set the standard deviation to something reasonable\n",
"lambda_train = softmax(model_out)\n",
"# Compute the log likelihood\n",
"nll = compute_negative_log_likelihood(y_train, lambda_train)\n",
@@ -365,7 +365,7 @@
"source": [
"# Define a range of values for the parameter\n",
"beta_1_vals = np.arange(-2,6.0,0.1)\n",
"# Create some arrays to store the likelihoods, negative log likehoods\n",
"# Create some arrays to store the likelihoods, negative log likelihoods\n",
"likelihoods = np.zeros_like(beta_1_vals)\n",
"nlls = np.zeros_like(beta_1_vals)\n",
"\n",

4
CM20315/CM20315_Shallow.ipynb
View File

@@ -233,7 +233,7 @@
"# TODO\n",
"# 1. Predict what effect changing phi_0 will have on the network. \n",
"# Answer:\n",
"# 2. Predict what effect multplying phi_1, phi_2, phi_3 by 0.5 would have. Check if you are correct\n",
"# 2. Predict what effect multiplying phi_1, phi_2, phi_3 by 0.5 would have. Check if you are correct\n",
"# Answer:\n",
"# 3. Predict what effect multiplying phi_1 by -1 will have. Check if you are correct.\n",
"# Answer:\n",
@@ -500,7 +500,7 @@
"print(\"Loss = %3.3f\"%(loss))\n",
"\n",
"# TODO. Manipulate the parameters (by hand!) to make the function \n",
"# fit the data better and try to reduct the loss to as small a number \n",
"# fit the data better and try to reduce the loss to as small a number \n",
"# as possible. The best that I could do was 0.181\n",
"# Tip... start by manipulating phi_0.\n",
"# It's not that easy, so don't spend too much time on this!"

6
CM20315/CM20315_Training_I.ipynb
View File

@@ -108,7 +108,7 @@
"source": [
"def line_search(loss_function, thresh=.0001, max_iter = 10, draw_flag = False):\n",
"\n",
" # Initialize four points along the rnage we are going to search\n",
" # Initialize four points along the range we are going to search\n",
" a = 0\n",
" b = 0.33\n",
" c = 0.66\n",
@@ -139,7 +139,7 @@
" # Rule #2 If point b is less than point c then\n",
" # then point d becomes point c, and\n",
" # point b becomes 1/3 between a and new d\n",
" # point c beocome 2/3 between a and new d \n",
" # point c becomes 2/3 between a and new d \n",
" # TODO REPLACE THE BLOCK OF CODE BELOW WITH THIS RULE\n",
" if (0):\n",
" continue;\n",
@@ -147,7 +147,7 @@
" # Rule #3 If point c is less than point b then\n",
" # then point a becomes point b, and\n",
" # point b becomes 1/3 between new a and d\n",
" # point c beocome 2/3 between new a and d \n",
" # point c becomes 2/3 between new a and d \n",
" # TODO REPLACE THE BLOCK OF CODE BELOW WITH THIS RULE\n",
" if(0):\n",
" continue\n",

8
CM20315/CM20315_Training_II.ipynb
View File

@@ -114,7 +114,7 @@
{
"cell_type": "code",
"source": [
"# Initialize the parmaeters and draw the model\n",
"# Initialize the parameters and draw the model\n",
"phi = np.zeros((2,1))\n",
"phi[0] = 0.6 # Intercept\n",
"phi[1] = -0.2 # Slope\n",
@@ -314,7 +314,7 @@
" return compute_loss(data[0,:], data[1,:], model, phi_start+ gradient * dist_prop)\n",
"\n",
"def line_search(data, model, phi, gradient, thresh=.00001, max_dist = 0.1, max_iter = 15, verbose=False):\n",
" # Initialize four points along the rnage we are going to search\n",
" # Initialize four points along the range we are going to search\n",
" a = 0\n",
" b = 0.33 * max_dist\n",
" c = 0.66 * max_dist\n",
@@ -345,7 +345,7 @@
" # Rule #2 If point b is less than point c then\n",
" # then point d becomes point c, and\n",
" # point b becomes 1/3 between a and new d\n",
" # point c beocome 2/3 between a and new d \n",
" # point c becomes 2/3 between a and new d \n",
" if lossb < lossc:\n",
" d = c\n",
" b = a+ (d-a)/3\n",
@@ -355,7 +355,7 @@
" # Rule #2 If point c is less than point b then\n",
" # then point a becomes point b, and\n",
" # point b becomes 1/3 between new a and d\n",
" # point c beocome 2/3 between new a and d \n",
" # point c becomes 2/3 between new a and d \n",
" a = b\n",
" b = a+ (d-a)/3\n",
" c = a+ 2*(d-a)/3\n",

6
CM20315/CM20315_Training_III.ipynb
View File

@@ -340,7 +340,7 @@
" return compute_loss(data[0,:], data[1,:], model, phi_start+ gradient * dist_prop)\n",
"\n",
"def line_search(data, model, phi, gradient, thresh=.00001, max_dist = 0.1, max_iter = 15, verbose=False):\n",
" # Initialize four points along the rnage we are going to search\n",
" # Initialize four points along the range we are going to search\n",
" a = 0\n",
" b = 0.33 * max_dist\n",
" c = 0.66 * max_dist\n",
@@ -371,7 +371,7 @@
" # Rule #2 If point b is less than point c then\n",
" # then point d becomes point c, and\n",
" # point b becomes 1/3 between a and new d\n",
" # point c beocome 2/3 between a and new d \n",
" # point c becomes 2/3 between a and new d \n",
" if lossb < lossc:\n",
" d = c\n",
" b = a+ (d-a)/3\n",
@@ -381,7 +381,7 @@
" # Rule #2 If point c is less than point b then\n",
" # then point a becomes point b, and\n",
" # point b becomes 1/3 between new a and d\n",
" # point c beocome 2/3 between new a and d \n",
" # point c becomes 2/3 between new a and d \n",
" a = b\n",
" b = a+ (d-a)/3\n",
" c = a+ 2*(d-a)/3\n",

6
CM20315/CM20315_Transformers.ipynb
View File

@@ -175,7 +175,7 @@
{
"cell_type": "code",
"source": [
"# TODO Modify the code below by changeing the number of tokens generated and the initial sentence\n",
"# TODO Modify the code below by changing the number of tokens generated and the initial sentence\n",
"# to get a feel for how well this works. Since I didn't reset the seed, it will give a different\n",
"# answer every time that you run it.\n",
"\n",
@@ -253,7 +253,7 @@
{
"cell_type": "code",
"source": [
"# TODO Modify the code below by changeing the number of tokens generated and the initial sentence\n",
"# TODO Modify the code below by changing the number of tokens generated and the initial sentence\n",
"# to get a feel for how well this works. \n",
"\n",
"# TODO Experiment with changing this line:\n",
@@ -471,7 +471,7 @@
{
"cell_type": "code",
"source": [
"# This routine reutnrs the k'th most likely next token.\n",
"# This routine returns the k'th most likely next token.\n",
"# If k =0 then it returns the most likely token, if k=1 it returns the next most likely and so on\n",
"# We will need this for beam search\n",
"def get_kth_most_likely_token(input_tokens, model, tokenizer, k):\n",

BIN
CM20315/Data/Data.zip Normal file
View File

Binary file not shown.

BIN
CM20315/Data/test_data_x.npy
View File

Binary file not shown.

BIN
CM20315/Data/test_data_y.npy
View File

Binary file not shown.

BIN
CM20315/Data/train_data_x.npy
View File

Binary file not shown.

BIN
CM20315/Data/val_data_x.npy
View File

Binary file not shown.

280
CM20315_2023/CM20315_Coursework_I.ipynb Normal file
View File

@@ -0,0 +1,280 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPNASgWoh4kBvxFP0xkN/I4",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/CM20315_2023/CM20315_Coursework_I.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# Coursework I -- Model hyperparameters\n",
"\n",
"The goal of the coursework is to modify a simple bit of numpy code that trains a network and measures the performance on a validation set for the MNIST 1D dataset.\n",
"\n",
"In this coursework, you need to modify the **model hyperparameters** (only) to improve the performance over the current attempt. This could mean the number of layers, the number of hidden units per layer, or the type of activation function, or any combination of the three.\n",
"\n",
"The only constraint is that you MUST use a fully connected network (no convolutional networks for now if you have read ahead in the book).\n",
"\n",
"You must improve the performance by at least 2% to get full marks.\n",
"\n",
"You will need to upload three things to Moodle:\n",
"1. The image that this notebook saves (click the folder icon on the left on colab to download it)\n",
"2. The lines of code you changed\n",
"3. The whole notebook as a .ipynb file. You can do this on the File menu\n",
"\n",
"\n"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import os\n",
"import torch, torch.nn as nn\n",
"from torch.utils.data import TensorDataset, DataLoader\n",
"from torch.optim.lr_scheduler import StepLR\n",
"import matplotlib.pyplot as plt\n",
"import random\n",
"import gdown"
],
"metadata": {
"id": "YrXWAH7sUWvU"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"\n",
"# Run this once to copy the train and validation data to your CoLab environment\n",
"# or download from my github to your local machine if you are doing this locally\n",
"if not os.path.exists('./Data.zip'):\n",
" !gdown 1HtnCrncY6dFCYqzgPf1HtPVAerTpwFRm\n",
" !unzip Data.zip"
],
"metadata": {
"id": "wScBGXXFVadm"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Load in the data\n",
"train_data_x = np.load('train_data_x.npy')\n",
"val_data_y = np.load('val_data_y.npy')\n",
"train_data_y = np.load('train_data_y.npy')\n",
"val_data_x = np.load('val_data_x.npy')\n",
"# Print out sizes\n",
"print(\"Train data: %d examples (columns), each of which has %d dimensions (rows)\"%((train_data_x.shape[1],train_data_x.shape[0])))\n",
"print(\"Validation data: %d examples (columns), each of which has %d dimensions (rows)\"%((val_data_x.shape[1],val_data_x.shape[0])))"
],
"metadata": {
"id": "8bKADvLHbiV5"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Define the network"
],
"metadata": {
"id": "_sFvRDGrl4qe"
}
},
{
"cell_type": "code",
"source": [
"# YOU SHOULD ONLY CHANGE THIS CELL!\n",
"\n",
"# There are 40 input dimensions and 10 output dimensions for this data\n",
"# The inputs correspond to the 40 offsets in the MNIST1D template.\n",
"D_i = 40\n",
"# The outputs correspond to the 10 digits\n",
"D_o = 10\n",
"\n",
"# Number of hidden units in layers 1 and 2\n",
"D_1 = 100\n",
"D_2 = 100\n",
"\n",
"# create model with two hidden layers\n",
"model = nn.Sequential(\n",
"nn.Linear(D_i, D_1),\n",
"nn.ReLU(),\n",
"nn.Linear(D_1, D_2),\n",
"nn.ReLU(),\n",
"nn.Linear(D_2, D_o))"
],
"metadata": {
"id": "FslroPJJffrh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# He initialization of weights\n",
"def weights_init(layer_in):\n",
" if isinstance(layer_in, nn.Linear):\n",
" nn.init.kaiming_uniform_(layer_in.weight)\n",
" layer_in.bias.data.fill_(0.0)"
],
"metadata": {
"id": "YgLaex1pfhqz"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# You need all this stuff to ensure that PyTorch is deterministic\n",
"def set_seed(seed):\n",
" torch.manual_seed(seed)\n",
" torch.cuda.manual_seed_all(seed)\n",
" torch.backends.cudnn.deterministic = True\n",
" torch.backends.cudnn.benchmark = False\n",
" np.random.seed(seed)\n",
" random.seed(seed)\n",
" os.environ['PYTHONHASHSEED'] = str(seed)"
],
"metadata": {
"id": "zXRmxCQNnL_M"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Set seed so always get same result (do not change)\n",
"set_seed(1)\n",
"\n",
"# choose cross entropy loss function (equation 5.24 in the loss notes)\n",
"loss_function = nn.CrossEntropyLoss()\n",
"# construct SGD optimizer and initialize learning rate and momentum\n",
"optimizer = torch.optim.SGD(model.parameters(), lr = 0.05, momentum=0.9)\n",
"# object that decreases learning rate by half every 10 epochs\n",
"scheduler = StepLR(optimizer, step_size=10, gamma=0.5)\n",
"# create 100 dummy data points and store in data loader class\n",
"x_train = torch.tensor(train_data_x.transpose().astype('float32'))\n",
"y_train = torch.tensor(train_data_y.astype('long'))\n",
"x_val= torch.tensor(val_data_x.transpose().astype('float32'))\n",
"y_val = torch.tensor(val_data_y.astype('long'))\n",
"\n",
"# load the data into a class that creates the batches\n",
"data_loader = DataLoader(TensorDataset(x_train,y_train), batch_size=100, shuffle=True, worker_init_fn=np.random.seed(1))\n",
"\n",
"# Initialize model weights\n",
"model.apply(weights_init)\n",
"\n",
"# loop over the dataset n_epoch times\n",
"n_epoch = 50\n",
"# store the loss and the % correct at each epoch\n",
"losses_train = np.zeros((n_epoch))\n",
"errors_train = np.zeros((n_epoch))\n",
"losses_val = np.zeros((n_epoch))\n",
"errors_val = np.zeros((n_epoch))\n",
"\n",
"for epoch in range(n_epoch):\n",
" # loop over batches\n",
" for i, data in enumerate(data_loader):\n",
" # retrieve inputs and labels for this batch\n",
" x_batch, y_batch = data\n",
" # zero the parameter gradients\n",
" optimizer.zero_grad()\n",
" # forward pass -- calculate model output\n",
" pred = model(x_batch)\n",
" # compute the lss\n",
" loss = loss_function(pred, y_batch)\n",
" # backward pass\n",
" loss.backward()\n",
" # SGD update\n",
" optimizer.step()\n",
"\n",
" # Run whole dataset to get statistics -- normally wouldn't do this\n",
" pred_train = model(x_train)\n",
" pred_val = model(x_val)\n",
" _, predicted_train_class = torch.max(pred_train.data, 1)\n",
" _, predicted_val_class = torch.max(pred_val.data, 1)\n",
" errors_train[epoch] = 100 - 100 * (predicted_train_class == y_train).float().sum() / len(y_train)\n",
" errors_val[epoch]= 100 - 100 * (predicted_val_class == y_val).float().sum() / len(y_val)\n",
" losses_train[epoch] = loss_function(pred_train, y_train).item()\n",
" losses_val[epoch]= loss_function(pred_val, y_val).item()\n",
" print(f'Epoch {epoch:5d}, train loss {losses_train[epoch]:.6f}, train error {errors_train[epoch]:3.2f}, val loss {losses_val[epoch]:.6f}, percent error {errors_val[epoch]:3.2f}')\n",
"\n",
" # tell scheduler to consider updating learning rate\n",
" scheduler.step()\n",
"\n",
"# Plot the results\n",
"fig, ax = plt.subplots()\n",
"ax.plot(errors_train,'r-',label='train')\n",
"ax.plot(errors_val,'b-',label='validation')\n",
"ax.set_ylim(0,100); ax.set_xlim(0,n_epoch)\n",
"ax.set_xlabel('Epoch'); ax.set_ylabel('Error')\n",
"ax.set_title('Part I: Validation Result %3.2f'%(errors_val[-1]))\n",
"ax.legend()\n",
"ax.plot([0,n_epoch],[37.45, 37.45],'k:') # Original results. You should be better than this!\n",
"plt.savefig('Coursework_I_Results.png',format='png')\n",
"plt.show()"
],
"metadata": {
"id": "NYw8I_3mmX5c"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Leave this all commented for now\n",
"# We'll see how well you did on the test data after the coursework is submitted\n",
"\n",
"# # I haven't given you this yet, leave commented\n",
"# test_data_x = np.load('test_data_x.npy')\n",
"# test_data_y = np.load('test_data_y.npy')\n",
"# x_test = torch.tensor(test_data_x.transpose().astype('float32'))\n",
"# y_test = torch.tensor(test_data_y.astype('long'))\n",
"# pred_test = model(x_test)\n",
"# _, predicted_test_class = torch.max(pred_test.data, 1)\n",
"# errors_test = 100 - 100 * (predicted_test_class == y_test).float().sum() / len(y_test)\n",
"# print(\"Test error = %3.3f\"%(errors_test))"
],
"metadata": {
"id": "O7nBz-R84QdJ"
},
"execution_count": null,
"outputs": []
}
]
}

276
CM20315_2023/CM20315_Coursework_II.ipynb Normal file
View File

@@ -0,0 +1,276 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyM+iKos5DEoHUxL8+9oxA2A",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/CM20315_2023/CM20315_Coursework_II.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# Coursework II -- Training hyperparameters\n",
"\n",
"The goal of the coursework is to modify a simple bit of numpy code that trains a network and measures the performance on a validation set for the MNist 1D dataset.\n",
"\n",
"In this coursework, you need to modify the **training hyperparameters** (only) to improve the performance over the current attempt. This could mean the training algorithm, learning rate, learning rate schedule, momentum term, initialization etc. \n",
"\n",
"You must improve the performance by at least 2% to get full marks.\n",
"\n",
"You will need to upload three things to Moodle:\n",
"1. The image that this notebook saves (click the folder icon on the left on colab to download it)\n",
"2. The lines of code you changed\n",
"3. The whole notebook as a .ipynb file. You can do this on the File menu"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import os\n",
"import torch, torch.nn as nn\n",
"from torch.utils.data import TensorDataset, DataLoader\n",
"from torch.optim.lr_scheduler import StepLR\n",
"import matplotlib.pyplot as plt\n",
"import random\n",
"import gdown"
],
"metadata": {
"id": "YrXWAH7sUWvU"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Run this once to copy the train and validation data to your CoLab environment\n",
"if not os.path.exists('./Data.zip'):\n",
" !gdown 1HtnCrncY6dFCYqzgPf1HtPVAerTpwFRm\n",
" !unzip Data.zip"
],
"metadata": {
"id": "wScBGXXFVadm"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Load in the data\n",
"train_data_x = np.load('train_data_x.npy',allow_pickle=True)\n",
"train_data_y = np.load('train_data_y.npy',allow_pickle=True)\n",
"val_data_x = np.load('val_data_x.npy',allow_pickle=True)\n",
"val_data_y = np.load('val_data_y.npy',allow_pickle=True)\n",
"# Print out sizes\n",
"print(\"Train data: %d examples (columns), each of which has %d dimensions (rows)\"%((train_data_x.shape[1],train_data_x.shape[0])))\n",
"print(\"Validation data: %d examples (columns), each of which has %d dimensions (rows)\"%((val_data_x.shape[1],val_data_x.shape[0])))"
],
"metadata": {
"id": "8bKADvLHbiV5"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Define the network"
],
"metadata": {
"id": "_sFvRDGrl4qe"
}
},
{
"cell_type": "code",
"source": [
"# YOU SHOULD NOT CHANGE THIS CELL!\n",
"\n",
"# There are 40 input dimensions and 10 output dimensions for this data\n",
"# The inputs correspond to the 40 offsets in the MNIST1D template.\n",
"D_i = 40\n",
"# The outputs correspond to the 10 digits\n",
"D_o = 10\n",
"\n",
"# Number of hidden units in layers 1 and 2\n",
"D_1 = 100\n",
"D_2 = 100\n",
"\n",
"# create model with two hidden layers\n",
"model = nn.Sequential(\n",
"nn.Linear(D_i, D_1),\n",
"nn.ReLU(),\n",
"nn.Linear(D_1, D_2),\n",
"nn.ReLU(),\n",
"nn.Linear(D_2, D_o))"
],
"metadata": {
"id": "FslroPJJffrh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# He initialization of weights\n",
"def weights_init(layer_in):\n",
" if isinstance(layer_in, nn.Linear):\n",
" nn.init.kaiming_uniform_(layer_in.weight)\n",
" layer_in.bias.data.fill_(0.0)"
],
"metadata": {
"id": "YgLaex1pfhqz"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# You need all this stuff to ensure that PyTorch is deterministic\n",
"def set_seed(seed):\n",
" torch.manual_seed(seed)\n",
" torch.cuda.manual_seed_all(seed)\n",
" torch.backends.cudnn.deterministic = True\n",
" torch.backends.cudnn.benchmark = False\n",
" np.random.seed(seed)\n",
" random.seed(seed)\n",
" os.environ['PYTHONHASHSEED'] = str(seed)"
],
"metadata": {
"id": "zXRmxCQNnL_M"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Set seed so always get same result (do not change)\n",
"set_seed(1)\n",
"\n",
"# choose cross entropy loss function (equation 5.24 in the loss notes)\n",
"loss_function = nn.CrossEntropyLoss()\n",
"# construct SGD optimizer and initialize learning rate and momentum\n",
"optimizer = torch.optim.SGD(model.parameters(), lr = 0.05, momentum=0.9)\n",
"# object that decreases learning rate by half every 10 epochs\n",
"scheduler = StepLR(optimizer, step_size=10, gamma=0.5)\n",
"# create 100 dummy data points and store in data loader class\n",
"x_train = torch.tensor(train_data_x.transpose().astype('float32'))\n",
"print(x_train.shape)\n",
"y_train = torch.tensor(train_data_y.astype('long'))\n",
"print(y_train.shape)\n",
"x_val= torch.tensor(val_data_x.transpose().astype('float32'))\n",
"y_val = torch.tensor(val_data_y.astype('long'))\n",
"\n",
"# load the data into a class that creates the batches\n",
"data_loader = DataLoader(TensorDataset(x_train,y_train), batch_size=100, shuffle=True, worker_init_fn=np.random.seed(1))\n",
"\n",
"# Initialize model weights\n",
"model.apply(weights_init)\n",
"\n",
"# loop over the dataset n_epoch times\n",
"n_epoch = 50\n",
"# store the loss and the % correct at each epoch\n",
"losses_train = np.zeros((n_epoch))\n",
"errors_train = np.zeros((n_epoch))\n",
"losses_val = np.zeros((n_epoch))\n",
"errors_val = np.zeros((n_epoch))\n",
"\n",
"for epoch in range(n_epoch):\n",
" # loop over batches\n",
" for i, data in enumerate(data_loader):\n",
" # retrieve inputs and labels for this batch\n",
" x_batch, y_batch = data\n",
" # zero the parameter gradients\n",
" optimizer.zero_grad()\n",
" # forward pass -- calculate model output\n",
" pred = model(x_batch)\n",
" # compute the lss\n",
" loss = loss_function(pred, y_batch)\n",
" # backward pass\n",
" loss.backward()\n",
" # SGD update\n",
" optimizer.step()\n",
"\n",
" # Run whole dataset to get statistics -- normally wouldn't do this\n",
" pred_train = model(x_train)\n",
" pred_val = model(x_val)\n",
" _, predicted_train_class = torch.max(pred_train.data, 1)\n",
" _, predicted_val_class = torch.max(pred_val.data, 1)\n",
" errors_train[epoch] = 100 - 100 * (predicted_train_class == y_train).float().sum() / len(y_train)\n",
" errors_val[epoch]= 100 - 100 * (predicted_val_class == y_val).float().sum() / len(y_val)\n",
" losses_train[epoch] = loss_function(pred_train, y_train).item()\n",
" losses_val[epoch]= loss_function(pred_val, y_val).item()\n",
" print(f'Epoch {epoch:5d}, train loss {losses_train[epoch]:.6f}, train error {errors_train[epoch]:3.2f}, val loss {losses_val[epoch]:.6f}, percent error {errors_val[epoch]:3.2f}')\n",
"\n",
" # tell scheduler to consider updating learning rate\n",
" scheduler.step()\n",
"\n",
"# Plot the results\n",
"fig, ax = plt.subplots()\n",
"ax.plot(errors_train,'r-',label='train')\n",
"ax.plot(errors_val,'b-',label='validation')\n",
"ax.set_ylim(0,100); ax.set_xlim(0,n_epoch)\n",
"ax.set_xlabel('Epoch'); ax.set_ylabel('Error')\n",
"ax.set_title('Part II: Validation Result %3.2f'%(errors_val[-1]))\n",
"ax.legend()\n",
"ax.plot([0,n_epoch],[37.45, 37.45],'k:') # Original results. You should be better than this!\n",
"plt.savefig('Coursework_II_Results.png',format='png')\n",
"plt.show()"
],
"metadata": {
"id": "NYw8I_3mmX5c"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Leave this all commented for now\n",
"# We'll see how well you did on the test data after the coursework is submitted\n",
"\n",
"# # I haven't given you this yet, leave commented\n",
"# test_data_x = np.load('test_data_x.npy')\n",
"# test_data_y = np.load('test_data_y.npy')\n",
"# x_test = torch.tensor(test_data_x.transpose().astype('float32'))\n",
"# y_test = torch.tensor(test_data_y.astype('long'))\n",
"# pred_test = model(x_test)\n",
"# _, predicted_test_class = torch.max(pred_test.data, 1)\n",
"# errors_test = 100 - 100 * (predicted_test_class == y_test).float().sum() / len(y_test)\n",
"# print(\"Test error = %3.3f\"%(errors_test))"
],
"metadata": {
"id": "O7nBz-R84QdJ"
},
"execution_count": null,
"outputs": []
}
]
}

275
CM20315_2023/CM20315_Coursework_III.ipynb Normal file
View File

@@ -0,0 +1,275 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyNDH1z3I76jjglu3o0LSlZc",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/CM20315_2023/CM20315_Coursework_III.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# Coursework III -- Regularization\n",
"\n",
"The goal of the coursework is to modify a simple bit of numpy code that trains a network and measures the performance on a validation set for the MNist 1D dataset.\n",
"\n",
"In this coursework, you need add **regularization** of some kind to improve the performance. Anything from chapter 9 of the book or anything else you can find is fine *except* early stopping. You must not change the model hyperparameters or the training algorithm.\n",
"\n",
"You must improve the performance by at least 2% to get full marks.\n",
"\n",
"You will need to upload three things to Moodle:\n",
"1. The image that this notebook saves (click the folder icon on the left on colab to download it)\n",
"2. The lines of code you changed\n",
"3. The whole notebook as a .ipynb file. You can do this on the File menu\n",
"\n",
"\n"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import os\n",
"import torch, torch.nn as nn\n",
"from torch.utils.data import TensorDataset, DataLoader\n",
"from torch.optim.lr_scheduler import StepLR\n",
"import matplotlib.pyplot as plt\n",
"import random\n",
"import gdown"
],
"metadata": {
"id": "YrXWAH7sUWvU"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Run this once to copy the train and validation data to your CoLab environment\n",
"if not os.path.exists('./Data.zip'):\n",
" !gdown 1HtnCrncY6dFCYqzgPf1HtPVAerTpwFRm\n",
" !unzip Data.zip"
],
"metadata": {
"id": "wScBGXXFVadm"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Load in the data\n",
"train_data_x = np.load('train_data_x.npy')\n",
"train_data_y = np.load('train_data_y.npy')\n",
"val_data_x = np.load('val_data_x.npy')\n",
"val_data_y = np.load('val_data_y.npy')\n",
"# Print out sizes\n",
"print(\"Train data: %d examples (columns), each of which has %d dimensions (rows)\"%((train_data_x.shape[1],train_data_x.shape[0])))\n",
"print(\"Validation data: %d examples (columns), each of which has %d dimensions (rows)\"%((val_data_x.shape[1],val_data_x.shape[0])))"
],
"metadata": {
"id": "8bKADvLHbiV5"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Define the network"
],
"metadata": {
"id": "_sFvRDGrl4qe"
}
},
{
"cell_type": "code",
"source": [
"# There are 40 input dimensions and 10 output dimensions for this data\n",
"# The inputs correspond to the 40 offsets in the MNIST1D template.\n",
"D_i = 40\n",
"# The outputs correspond to the 10 digits\n",
"D_o = 10\n",
"\n",
"# Number of hidden units in layers 1 and 2\n",
"D_1 = 100\n",
"D_2 = 100\n",
"\n",
"# create model with two hidden layers\n",
"model = nn.Sequential(\n",
"nn.Linear(D_i, D_1),\n",
"nn.ReLU(),\n",
"nn.Linear(D_1, D_2),\n",
"nn.ReLU(),\n",
"nn.Linear(D_2, D_o))"
],
"metadata": {
"id": "FslroPJJffrh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# He initialization of weights\n",
"def weights_init(layer_in):\n",
" if isinstance(layer_in, nn.Linear):\n",
" nn.init.kaiming_uniform_(layer_in.weight)\n",
" layer_in.bias.data.fill_(0.0)"
],
"metadata": {
"id": "YgLaex1pfhqz"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# You need all this stuff to ensure that PyTorch is deterministic\n",
"def set_seed(seed):\n",
" torch.manual_seed(seed)\n",
" torch.cuda.manual_seed_all(seed)\n",
" torch.backends.cudnn.deterministic = True\n",
" torch.backends.cudnn.benchmark = False\n",
" np.random.seed(seed)\n",
" random.seed(seed)\n",
" os.environ['PYTHONHASHSEED'] = str(seed)"
],
"metadata": {
"id": "zXRmxCQNnL_M"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Set seed so always get same result (do not change)\n",
"set_seed(1)\n",
"\n",
"# choose cross entropy loss function (equation 5.24 in the loss notes)\n",
"loss_function = nn.CrossEntropyLoss()\n",
"# construct SGD optimizer and initialize learning rate and momentum\n",
"optimizer = torch.optim.SGD(model.parameters(), lr = 0.05, momentum=0.9)\n",
"# object that decreases learning rate by half every 10 epochs\n",
"scheduler = StepLR(optimizer, step_size=10, gamma=0.5)\n",
"# create 100 dummy data points and store in data loader class\n",
"x_train = torch.tensor(train_data_x.transpose().astype('float32'))\n",
"y_train = torch.tensor(train_data_y.astype('long'))\n",
"x_val= torch.tensor(val_data_x.transpose().astype('float32'))\n",
"y_val = torch.tensor(val_data_y.astype('long'))\n",
"\n",
"# load the data into a class that creates the batches\n",
"data_loader = DataLoader(TensorDataset(x_train,y_train), batch_size=100, shuffle=True, worker_init_fn=np.random.seed(1))\n",
"\n",
"# Initialize model weights\n",
"model.apply(weights_init)\n",
"\n",
"# loop over the dataset n_epoch times\n",
"n_epoch = 50\n",
"# store the loss and the % correct at each epoch\n",
"losses_train = np.zeros((n_epoch))\n",
"errors_train = np.zeros((n_epoch))\n",
"losses_val = np.zeros((n_epoch))\n",
"errors_val = np.zeros((n_epoch))\n",
"\n",
"for epoch in range(n_epoch):\n",
" # loop over batches\n",
" for i, data in enumerate(data_loader):\n",
" # retrieve inputs and labels for this batch\n",
" x_batch, y_batch = data\n",
" # zero the parameter gradients\n",
" optimizer.zero_grad()\n",
" # forward pass -- calculate model output\n",
" pred = model(x_batch)\n",
" # compute the lss\n",
" loss = loss_function(pred, y_batch)\n",
" # backward pass\n",
" loss.backward()\n",
" # SGD update\n",
" optimizer.step()\n",
"\n",
" # Run whole dataset to get statistics -- normally wouldn't do this\n",
" pred_train = model(x_train)\n",
" pred_val = model(x_val)\n",
" _, predicted_train_class = torch.max(pred_train.data, 1)\n",
" _, predicted_val_class = torch.max(pred_val.data, 1)\n",
" errors_train[epoch] = 100 - 100 * (predicted_train_class == y_train).float().sum() / len(y_train)\n",
" errors_val[epoch]= 100 - 100 * (predicted_val_class == y_val).float().sum() / len(y_val)\n",
" losses_train[epoch] = loss_function(pred_train, y_train).item()\n",
" losses_val[epoch]= loss_function(pred_val, y_val).item()\n",
" print(f'Epoch {epoch:5d}, train loss {losses_train[epoch]:.6f}, train error {errors_train[epoch]:3.2f}, val loss {losses_val[epoch]:.6f}, percent error {errors_val[epoch]:3.2f}')\n",
"\n",
" # tell scheduler to consider updating learning rate\n",
" scheduler.step()\n",
"\n",
"# Plot the results\n",
"fig, ax = plt.subplots()\n",
"ax.plot(errors_train,'r-',label='train')\n",
"ax.plot(errors_val,'b-',label='validation')\n",
"ax.set_ylim(0,100); ax.set_xlim(0,n_epoch)\n",
"ax.set_xlabel('Epoch'); ax.set_ylabel('Error')\n",
"ax.set_title('Part III: Validation Result %3.2f'%(errors_val[-1]))\n",
"ax.legend()\n",
"ax.plot([0,n_epoch],[37.45, 37.45],'k:') # Original results. You should be better than this!\n",
"plt.savefig('Coursework_III_Results.png',format='png')\n",
"plt.show()"
],
"metadata": {
"id": "NYw8I_3mmX5c"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Leave this all commented for now\n",
"# We'll see how well you did on the test data after the coursework is submitted\n",
"\n",
"\n",
"# # I haven't given you this yet, leave commented\n",
"# test_data_x = np.load('test_data_x.npy')\n",
"# test_data_y = np.load('test_data_y.npy')\n",
"# x_test = torch.tensor(test_data_x.transpose().astype('float32'))\n",
"# y_test = torch.tensor(test_data_y.astype('long'))\n",
"# pred_test = model(x_test)\n",
"# _, predicted_test_class = torch.max(pred_test.data, 1)\n",
"# errors_test = 100 - 100 * (predicted_test_class == y_test).float().sum() / len(y_test)\n",
"# print(\"Test error = %3.3f\"%(errors_test))"
],
"metadata": {
"id": "O7nBz-R84QdJ"
},
"execution_count": null,
"outputs": []
}
]
}

212
CM20315_2023/CM20315_Coursework_IV.ipynb Normal file
View File

@@ -0,0 +1,212 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyMrWYwQrwgJvDza1vhYK9WQ",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/CM20315_2023/CM20315_Coursework_IV.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# Coursework IV\n",
"\n",
"This coursework explores the geometry of high dimensional spaces. It doesn't behave how you would expect and all your intuitions are wrong! You will write code and it will give you three numerical answers that you need to type into Moodle."
],
"metadata": {
"id": "EjLK-kA1KnYX"
}
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "4ESMmnkYEVAb"
},
"outputs": [],
"source": [
"import numpy as np\n",
"import matplotlib.pyplot as plt\n",
"import scipy.special as sci"
]
},
{
"cell_type": "markdown",
"source": [
"# Part (a)\n",
"\n",
"In part (a) of the practical, we investigate how close random points are in 2D, 100D, and 1000D. In each case, we generate 1000 points and calculate the Euclidean distance between each pair. You should find that in 1000D, the furthest two points are only slightly further apart than the nearest points. Weird!"
],
"metadata": {
"id": "MonbPEitLNgN"
}
},
{
"cell_type": "code",
"source": [
"# Fix the random seed so we all have the same random numbers\n",
"np.random.seed(0)\n",
"n_data = 1000\n",
"# Create 1000 data examples (columns) each with 2 dimensions (rows)\n",
"n_dim = 2\n",
"x_2D = np.random.normal(size=(n_dim,n_data))\n",
"# Create 1000 data examples (columns) each with 100 dimensions (rows)\n",
"n_dim = 100\n",
"x_100D = np.random.normal(size=(n_dim,n_data))\n",
"# Create 1000 data examples (columns) each with 1000 dimensions (rows)\n",
"n_dim = 1000\n",
"x_1000D = np.random.normal(size=(n_dim,n_data))\n",
"\n",
"# These values should be the same, otherwise your answer will be wrong\n",
"# Get in touch if they are not!\n",
"print('Sum of your data is %3.3f, Should be %3.3f'%(np.sum(x_1000D),1036.321))"
],
"metadata": {
"id": "vZSHVmcWEk14"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"def distance_ratio(x):\n",
" # TODO -- replace the two lines below to calculate the largest and smallest Euclidean distance between\n",
" # the data points in the columns of x. DO NOT include the distance between the data point\n",
" # and itself (which is obviously zero)\n",
" smallest_dist = 1.0\n",
" largest_dist = 1.0\n",
"\n",
" # Calculate the ratio and return\n",
" dist_ratio = largest_dist / smallest_dist\n",
" return dist_ratio"
],
"metadata": {
"id": "PhVmnUs8ErD9"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"print('Ratio of largest to smallest distance 2D: %3.3f'%(distance_ratio(x_2D)))\n",
"print('Ratio of largest to smallest distance 100D: %3.3f'%(distance_ratio(x_100D)))\n",
"print('Ratio of largest to smallest distance 1000D: %3.3f'%(distance_ratio(x_1000D)))\n",
"print('**Note down the last of these three numbers, you will need to submit it for your coursework**')"
],
"metadata": {
"id": "0NdPxfn5GQuJ"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Part (b)\n",
"\n",
"In part (b) of the practical we calculate the volume of a hypersphere of radius 0.5 (i.e., of diameter 1) as a function of the radius. You will find that the volume decreases to almost nothing in high dimensions. All of the volume is in the corners of the unit hypercube (which always has volume 1). Double weird.\n",
"\n",
"Note that you you can check your answer by doing the calculation for 2D using the standard formula for the area of a circle and making sure it matches."
],
"metadata": {
"id": "b2FYKV1SL4Z7"
}
},
{
"cell_type": "code",
"source": [
"def volume_of_hypersphere(diameter, dimensions):\n",
" # Formula given in Problem 8.7 of the notes\n",
" # You will need sci.gamma()\n",
" # Check out: https://docs.scipy.org/doc/scipy/reference/generated/scipy.special.gamma.html\n",
" # Also use this value for pi\n",
" pi = np.pi\n",
" # TODO replace this code with formula for the volume of a hypersphere\n",
" volume = 1.0\n",
"\n",
" return volume\n"
],
"metadata": {
"id": "CZoNhD8XJaHR"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"diameter = 1.0\n",
"for c_dim in range(1,11):\n",
" print(\"Volume of unit diameter hypersphere in %d dimensions is %3.3f\"%(c_dim, volume_of_hypersphere(diameter, c_dim)))\n",
"print('**Note down the last of these ten numbers, you will need to submit it for your coursework**')"
],
"metadata": {
"id": "fNTBlg_GPEUh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Part (c)\n",
"\n",
"In part (c) of the coursework, you will calculate what proportion of the volume of a hypersphere is in the outer 1% of the radius/diameter. Calculate the volume of a hypersphere and then the volume of a hypersphere with 0.99 of the radius and then figure out the proportion (a number between 0 and 1). You'll see that by the time we get to 300 dimensions most of the volume is in the outer 1 percent. Extremely weird!"
],
"metadata": {
"id": "GdyMeOBmoXyF"
}
},
{
"cell_type": "code",
"source": [
"def get_prop_of_volume_in_outer_1_percent(dimension):\n",
" # TODO -- replace this line\n",
" proportion = 1.0\n",
"\n",
" return proportion"
],
"metadata": {
"id": "8_CxZ2AIpQ8w"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# While we're here, let's look at how much of the volume is in the outer 1% of the radius\n",
"for c_dim in [1,2,10,20,50,100,150,200,250,300]:\n",
" print('Proportion of volume in outer 1 percent of radius in %d dimensions =%3.3f'%(c_dim, get_prop_of_volume_in_outer_1_percent(c_dim)))\n",
"print('**Note down the last of these ten numbers, you will need to submit it for your coursework**')"
],
"metadata": {
"id": "LtMDIn2qPVfJ"
},
"execution_count": null,
"outputs": []
}
]
}

525
CM20315_2023/CM20315_Coursework_V_2023.ipynb Normal file
View File

@@ -0,0 +1,525 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyN7KaQQ63bf52r+b5as0MkK",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/CM20315_2023/CM20315_Coursework_V_2023.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# **Coursework V: Backpropagation in Toy Model**\n",
"\n",
"This notebook computes the derivatives of a toy function similar (but different from) that in section 7.3 of the book.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions. At various points, you will get an answer that you need to copy into Moodle to be marked.\n",
"\n",
"Post to the content forum if you find any mistakes or need to clarify something."
],
"metadata": {
"id": "pOZ6Djz0dhoy"
}
},
{
"cell_type": "markdown",
"source": [
"# Problem setting\n",
"\n",
"We're going to investigate how to take the derivatives of functions where one operation is composed with another, which is composed with a third and so on. For example, consider the model:\n",
"\n",
"\\begin{equation}\n",
" \\mbox{f}[x,\\boldsymbol\\phi] = \\beta_3+\\omega_3\\cdot\\mbox{PReLU}\\Bigl[\\gamma, \\beta_2+\\omega_2\\cdot\\mbox{PReLU}\\bigl[\\gamma, \\beta_1+\\omega_1\\cdot\\mbox{PReLU}[\\gamma, \\beta_0+\\omega_0x]\\bigr]\\Bigr],\n",
"\\end{equation}\n",
"\n",
"with parameters $\\boldsymbol\\phi=\\{\\beta_0,\\omega_0,\\beta_1,\\omega_1,\\beta_2,\\omega_2,\\beta_3,\\omega_3\\}$, where\n",
"\n",
"\\begin{equation}\n",
"\\mbox{PReLU}[\\gamma, z] = \\begin{cases} \\gamma\\cdot z & \\quad z \\leq0 \\\\ z & \\quad z> 0\\end{cases}.\n",
"\\end{equation}\n",
"\n",
"Suppose that we have a binary cross-entropy loss function (equation 5.20 from the book):\n",
"\n",
"\\begin{equation*}\n",
"\\ell_i = -(1-y_{i})\\log\\Bigl[1-\\mbox{sig}[\\mbox{f}[\\mathbf{x}_i,\\boldsymbol\\phi]]\\Bigr] - y_{i}\\log\\Bigl[\\mbox{sig}[\\mbox{f}[\\mathbf{x}_i,\\boldsymbol\\phi]]\\Bigr].\n",
"\\end{equation*}\n",
"\n",
"Assume that we know the current values of $\\beta_{0},\\beta_{1},\\beta_{2},\\beta_{3},\\omega_{0},\\omega_{1},\\omega_{2},\\omega_{3}$, $\\gamma$, $x_i$ and $y_i$. We want to know how $\\ell_i$ changes when we make a small change to $\\beta_{0},\\beta_{1},\\beta_{2},\\beta_{3},\\omega_{0},\\omega_{1},\\omega_{2}$, or $\\omega_{3}$. In other words, we want to compute the eight derivatives:\n",
"\n",
"\\begin{eqnarray*}\n",
"\\frac{\\partial \\ell_i}{\\partial \\beta_{0}}, \\quad \\frac{\\partial \\ell_i}{\\partial \\beta_{1}}, \\quad \\frac{\\partial \\ell_i}{\\partial \\beta_{2}}, \\quad \\frac{\\partial \\ell_i }{\\partial \\beta_{3}}, \\quad \\frac{\\partial \\ell_i}{\\partial \\omega_{0}}, \\quad \\frac{\\partial \\ell_i}{\\partial \\omega_{1}}, \\quad \\frac{\\partial \\ell_i}{\\partial \\omega_{2}}, \\quad\\mbox{and} \\quad \\frac{\\partial \\ell_i}{\\partial \\omega_{3}}.\n",
"\\end{eqnarray*}"
],
"metadata": {
"id": "1DmMo2w63CmT"
}
},
{
"cell_type": "code",
"source": [
"# import library\n",
"import numpy as np"
],
"metadata": {
"id": "RIPaoVN834Lj"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Let's first define the original function and the loss term:"
],
"metadata": {
"id": "32-ufWhc3v2c"
}
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "AakK_qen3BpU"
},
"outputs": [],
"source": [
"# Defines the activation function\n",
"def paramReLU(gamma,x):\n",
" if x > 0:\n",
" return x\n",
" else:\n",
" return x * gamma\n",
"\n",
"# Defines the main function\n",
"def fn(x, beta0, beta1, beta2, beta3, omega0, omega1, omega2, omega3, gamma):\n",
" return beta3+omega3 * paramReLU(gamma, beta2 + omega2 * paramReLU(gamma, beta1 + omega1 * paramReLU(gamma, beta0 + omega0 * x)))\n",
"\n",
"# Logistic sigmoid\n",
"def sig(z):\n",
" return 1./(1+np.exp(-z))\n",
"\n",
"# The loss function (equation 5.20 from book)\n",
"def loss(f,y):\n",
" sig_net_out = sig(f)\n",
" l = -(1-y) * np.log(1-sig_net_out) - y * np.log(sig_net_out)\n",
" return l"
]
},
{
"cell_type": "markdown",
"source": [
"Now we'll choose some values for the betas and the omegas and x and compute the output of the function:"
],
"metadata": {
"id": "y7tf0ZMt5OXt"
}
},
{
"cell_type": "code",
"source": [
"beta0 = 1.0; beta1 = -2.0; beta2 = -3.0; beta3 = 0.4\n",
"omega0 = 0.1; omega1 = -0.4; omega2 = 2.0; omega3 = -3.0\n",
"gamma = 0.2\n",
"x = 2.3; y =1.0\n",
"f_val = fn(x,beta0,beta1,beta2,beta3,omega0,omega1,omega2,omega3, gamma)\n",
"l_i_func = loss(f_val, y)\n",
"print('Loss full function = %3.3f'%l_i_func)"
],
"metadata": {
"id": "pwvOcCxr41X_"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Forward pass\n",
"\n",
"We compute a series of intermediate values $f_0, h_0, f_1, h_1, f_2, h_2, f_3$, and finally the loss $\\ell$"
],
"metadata": {
"id": "W6ZP62T5fU64"
}
},
{
"cell_type": "code",
"source": [
"x = 2.3; y =1.0\n",
"gamma = 0.2\n",
"# Compute all the f_k and h_k terms\n",
"# I've done the first two for you\n",
"f0 = beta0+omega0 * x\n",
"h1 = paramReLU(gamma, f0)\n",
"\n",
"\n",
"# TODO: Replace the code below\n",
"f1 = 0\n",
"h2 = 0\n",
"f2 = 0\n",
"h3 = 0\n",
"f3 = 0\n",
"\n",
"\n",
"# Compute the loss and print\n",
"# The answer should be the same as when we computed the full function above\n",
"l_i = loss(f3, y)\n",
"print(\"Loss forward pass = %3.3f\"%(l_i))\n"
],
"metadata": {
"id": "z-BckTpMf5PL"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Backward pass: Derivative of loss function with respect to function output\n",
"\n",
"Now, we'll compute the derivative $\\frac{dl}{df_3}$ of the loss function with respect to the network output $f_3$. In other words, we are asking how does the loss change as we make a small change in the network output.\n",
"\n",
"Since the loss it itself a function of $\\mbox{sig}[f_3]$ we'll compute this using the chain rule:\n",
"\n",
"\\begin{equation}\n",
"\\frac{dl}{df_3} = \\frac{d\\mbox{sig}[f_3]}{df_3}\\cdot \\frac{dl}{d\\mbox{sig}[f_3]}\n",
"\\end{equation}\n",
"\n",
"Your job is to compute the two quantities on the right hand side.\n"
],
"metadata": {
"id": "TbFbxz64Xz4I"
}
},
{
"cell_type": "code",
"source": [
"# Compute the derivative of the the loss with respect to the function output f_val\n",
"def dl_df(f_val,y):\n",
" # Compute sigmoid of network output\n",
" sig_f_val = sig(f_val)\n",
" # Compute the derivative of loss with respect to network output using chain rule\n",
" dl_df_val = dsig_df(f_val) * dl_dsigf(sig_f_val, y)\n",
" # Return the derivative\n",
" return dl_df_val"
],
"metadata": {
"id": "ZWKAq6HC90qV"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# MOODLE ANSWER # Notebook V 1a: Copy this code when you have finished it.\n",
"\n",
"# Compute the derivative of the logistic sigmoid function with respect to its input (as a closed form solution)\n",
"def dsig_df(f_val):\n",
" # TODO Write this function\n",
" # Replace this line:\n",
" return 1\n",
"\n",
"# Compute the derivative of the loss with respect to the logistic sigmoid (as a closed form solution)\n",
"def dl_dsigf(sig_f_val, y):\n",
" # TODO Write this function\n",
" # Replace this line:\n",
" return 1"
],
"metadata": {
"id": "lIngYAgPq-5I"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Let's run that for some f_val, y. Check previous practicals to see how you can check whether your answer is correct."
],
"metadata": {
"id": "Q-j-i8khXzbK"
}
},
{
"cell_type": "code",
"source": [
"y = 0.0\n",
"dl_df3 = dl_df(f3,y)\n",
"print(\"Moodle Answer Notebook V 1b: dldh3=%3.3f\"%(dl_df3))\n",
"\n",
"y= 1.0\n",
"dl_df3 = dl_df(f3,y)\n",
"print(\"Moodle Answer Notebook V 1c: dldh3=%3.3f\"%(dl_df3))"
],
"metadata": {
"id": "Z7Lb5BibY50H"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Backward pass: Derivative of activation function with respect to preactivations\n",
"\n",
"Write a function to compute the derivative $\\frac{\\partial h}{\\partial f}$ of the activation function (parametric ReLU) with respect to its input.\n"
],
"metadata": {
"id": "BA7QaOzejzZw"
}
},
{
"cell_type": "code",
"source": [
"# MOODLE ANSWER Notebook V 2a: Copy this code when you have finished it.\n",
"\n",
"def dh_df(gamma, f_val):\n",
" # TODO: Write this function\n",
" # Replace this line:\n",
" return 1\n"
],
"metadata": {
"id": "bBPfPg04j-Qw"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Let's run that for some values of f_val. Check previous practicals to see how you can check whether your answer is correct."
],
"metadata": {
"id": "QRNCM0EGk9-w"
}
},
{
"cell_type": "code",
"source": [
"f_val_test = 0.6\n",
"dh_df_val = dh_df(gamma, f_val_test)\n",
"print(\"Moodle Answer Notebook V 2b: dhdf=%3.3f\"%(dh_df_val))\n",
"\n",
"f_val_test = -0.4\n",
"dh_df_val = dh_df(gamma, f_val_test)\n",
"print(\"Moodle Answer Notebook V 2c: dhdf=%3.3f\"%(dh_df_val))"
],
"metadata": {
"id": "bql8VZIGk8Wy"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
" # Backward pass: Compute the derivatives of $l_i$ with respect to the intermediate quantities but in reverse order:\n",
"\n",
"\\begin{eqnarray}\n",
"\\frac{\\partial \\ell_i}{\\partial h_3}, \\quad \\frac{\\partial \\ell_i}{\\partial f_2}, \\quad\n",
"\\frac{\\partial \\ell_i}{\\partial h_2}, \\quad \\frac{\\partial \\ell_i}{\\partial f_1}, \\quad\\frac{\\partial \\ell_i}{\\partial h_1}, \\quad\\mbox{and} \\quad \\frac{\\partial \\ell_i}{\\partial f_0}.\n",
"\\end{eqnarray}\n",
"\n",
"The first of these derivatives can be calculated using the chain rule:\n",
"\n",
"\\begin{equation}\n",
"\\frac{\\partial \\ell_i}{\\partial h_{3}} =\\frac{\\partial f_{3}}{\\partial h_{3}} \\frac{\\partial \\ell_i}{\\partial f_{3}} .\n",
"\\end{equation}\n",
"\n",
"The left-hand side asks how $\\ell_i$ changes when $h_{3}$ changes. The right-hand side says we can decompose this into (i) how $\\ell_i$ changes when $f_{3}$ changes and how $f_{3}$ changes when $h_{3}$ changes. So you get a chain of events happening: $h_{3}$ changes $f_{3}$, which changes $\\ell_i$, and the derivatives represent the effects of this chain. Notice that we computed the first of these derivatives already. The second term is the derivative of $\\beta_{3} + \\omega_{3}h_{3}$ with respect to $h_3$ which is simply $\\omega_3$. \n",
"\n",
"We can continue in this way, computing the derivatives of the output with respect to these intermediate quantities:\n",
"\n",
"\\begin{eqnarray}\n",
"\\frac{\\partial \\ell_i}{\\partial f_{2}} &=& \\frac{\\partial h_{3}}{\\partial f_{2}}\\left(\n",
"\\frac{\\partial f_{3}}{\\partial h_{3}}\\frac{\\partial \\ell_i}{\\partial f_{3}} \\right)\n",
"\\nonumber \\\\\n",
"\\frac{\\partial \\ell_i}{\\partial h_{2}} &=& \\frac{\\partial f_{2}}{\\partial h_{2}}\\left(\\frac{\\partial h_{3}}{\\partial f_{2}}\\frac{\\partial f_{3}}{\\partial h_{3}}\\frac{\\partial \\ell_i}{\\partial f_{3}}\\right)\\nonumber \\\\\n",
"\\frac{\\partial \\ell_i}{\\partial f_{1}} &=& \\frac{\\partial h_{2}}{\\partial f_{1}}\\left( \\frac{\\partial f_{2}}{\\partial h_{2}}\\frac{\\partial h_{3}}{\\partial f_{2}}\\frac{\\partial f_{3}}{\\partial h_{3}}\\frac{\\partial \\ell_i}{\\partial f_{3}} \\right)\\nonumber \\\\\n",
"\\frac{\\partial \\ell_i}{\\partial h_{1}} &=& \\frac{\\partial f_{1}}{\\partial h_{1}}\\left(\\frac{\\partial h_{2}}{\\partial f_{1}} \\frac{\\partial f_{2}}{\\partial h_{2}}\\frac{\\partial h_{3}}{\\partial f_{2}}\\frac{\\partial f_{3}}{\\partial h_{3}}\\frac{\\partial \\ell_i}{\\partial f_{3}} \\right)\\nonumber \\\\\n",
"\\frac{\\partial \\ell_i}{\\partial f_{0}} &=& \\frac{\\partial h_{1}}{\\partial f_{0}}\\left(\\frac{\\partial f_{1}}{\\partial h_{1}}\\frac{\\partial h_{2}}{\\partial f_{1}} \\frac{\\partial f_{2}}{\\partial h_{2}}\\frac{\\partial h_{3}}{\\partial f_{2}}\\frac{\\partial f_{3}}{\\partial h_{3}}\\frac{\\partial \\ell_i}{\\partial f_{3}} \\right).\n",
"\\end{eqnarray}\n",
"\n",
"In each case, we have already computed all of the terms except the last one in the previous step, and the last term is simple to evaluate. This is called the **backward pass**."
],
"metadata": {
"id": "jay8NYWdFHuZ"
}
},
{
"cell_type": "code",
"source": [
"x = 2.3; y =1.0\n",
"dldf3 = dl_df(f3,y)"
],
"metadata": {
"id": "RSC_2CIfKF1b"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# MOODLE ANSWER Notebook V 3a: Copy this code when you have finished it.\n",
"# TODO -- Compute the derivatives of the output with respect\n",
"# to the intermediate computations h_k and f_k (i.e, run the backward pass)\n",
"# I've done the first two for you. You replace the code below:\n",
"# Replace the code below\n",
"dldh3 = 1\n",
"dldf2 = 1\n",
"dldh2 = 1\n",
"dldf1 = 1\n",
"dldh1 = 1\n",
"dldf0 = 1"
],
"metadata": {
"id": "gCQJeI--Egdl"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Finally, we consider how the loss~$\\ell_{i}$ changes when we change the parameters $\\beta_{\\bullet}$ and $\\omega_{\\bullet}$. Once more, we apply the chain rule:\n",
"\n",
"\n",
"\n",
"\n",
"\\begin{eqnarray}\n",
"\\frac{\\partial \\ell_i}{\\partial \\beta_{k}} &=& \\frac{\\partial f_{k}}{\\partial \\beta_{k}}\\frac{\\partial \\ell_i}{\\partial f_{k}}\\nonumber \\\\\n",
"\\frac{\\partial \\ell_i}{\\partial \\omega_{k}} &=& \\frac{\\partial f_{k}}{\\partial \\omega_{k}}\\frac{\\partial \\ell_i}{\\partial f_{k}}.\n",
"\\end{eqnarray}\n",
"\n",
"\\noindent In each case, the second term on the right-hand side was computed in step 2. When $k>0$, we have~$f_{k}=\\beta_{k}+\\omega_k \\cdot h_{k}$, so:\n",
"\n",
"\\begin{eqnarray}\n",
"\\frac{\\partial f_{k}}{\\partial \\beta_{k}} = 1 \\quad\\quad\\mbox{and}\\quad \\quad \\frac{\\partial f_{k}}{\\partial \\omega_{k}} &=& h_{k}.\n",
"\\end{eqnarray}"
],
"metadata": {
"id": "FlzlThQPGpkU"
}
},
{
"cell_type": "code",
"source": [
"# MOODLE ANSWER Notebook V 3b: Copy this code when you have finished it.\n",
"# TODO -- Calculate the final derivatives with respect to the beta and omega terms\n",
"# Replace these terms\n",
"dldbeta3 = 1\n",
"dldomega3 = 1\n",
"dldbeta2 = 1\n",
"dldomega2 = 1\n",
"dldbeta1 = 1\n",
"dldomega1 = 1\n",
"dldbeta0 = 1\n",
"dldomega0 = 1"
],
"metadata": {
"id": "1I2BhqZhGMK6"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Print the last two values out (enter these into Moodle). Again, think about how you can test whether these are correct.\n",
"print('Moodle Answer Notebook V 3c: dldbeta0=%3.3f'%(dldbeta0))\n",
"print('Moodle Answer Notebook V 3d: dldOmega0=%3.3f'%(dldomega0))"
],
"metadata": {
"id": "38eiOn2aHgHI"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Compute the derivatives of $\\ell_i$ with respect to the parmeter $\\gamma$ of the parametric ReLU function. \n",
"\n",
"In other words, compute:\n",
"\n",
"\\begin{equation}\n",
"\\frac{d\\ell_i}{d\\gamma}\n",
"\\end{equation}\n",
"\n",
"Along the way, we will need to compute derivatives\n",
"\n",
"\\begin{equation}\n",
"\\frac{dh_k(\\gamma,f_{k-1})}{d\\gamma}\n",
"\\end{equation}\n",
"\n",
"This is quite difficult and not worth many marks, so don't spend too much time on it if you are confused!"
],
"metadata": {
"id": "lhD5AoUHx3DS"
}
},
{
"cell_type": "code",
"source": [
"# Computes how an activation changes with a small change in gamma assuming preactivations are f\n",
"# MOODLE ANSWER # Notebook V 4a: Copy this code when you have finished it.\n",
"def dhdgamma(gamma, f):\n",
" # TODO -- Write this function\n",
" # Replace this line\n",
" return 1"
],
"metadata": {
"id": "yC-9MTQevliP"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Compute how the loss changes with gamma\n",
"# Replace this line:\n",
"# MOODLE ANSWER # Notebook V 4b: Copy this code when you have finished it.\n",
"dldgamma = 1"
],
"metadata": {
"id": "DiNQrveoLuHR"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"print(\"Moodle Answer Notebook V 4c: dldgamma = %3.3f\"%(dldgamma))"
],
"metadata": {
"id": "YHxmAEnxzy3O"
},
"execution_count": null,
"outputs": []
}
]
}

8
Notebooks/Chap01/1_1_BackgroundMathematics.ipynb
View File

@@ -83,7 +83,7 @@
"source": [
"# Plot the 1D linear function\n",
"\n",
"# Define an array of x values from 0 to 10 with increments of 0.1\n",
"# Define an array of x values from 0 to 10 with increments of 0.01\n",
"# https://numpy.org/doc/stable/reference/generated/numpy.arange.html\n",
"x = np.arange(0.0,10.0, 0.01)\n",
"# Compute y using the function you filled in above\n",
@@ -171,7 +171,7 @@
"# Color represents y value (brighter = higher value)\n",
"# Black = -10 or less, White = +10 or more\n",
"# 0 = mid orange\n",
"# Lines are conoturs where value is equal\n",
"# Lines are contours where value is equal\n",
"draw_2D_function(x1,x2,y)\n",
"\n",
"# TODO\n",
@@ -308,7 +308,7 @@
"source": [
"# Draw the exponential function\n",
"\n",
"# Define an array of x values from -5 to 5 with increments of 0.1\n",
"# Define an array of x values from -5 to 5 with increments of 0.01\n",
"x = np.arange(-5.0,5.0, 0.01)\n",
"y = np.exp(x) ;\n",
"\n",
@@ -354,7 +354,7 @@
"source": [
"# Draw the logarithm function\n",
"\n",
"# Define an array of x values from -5 to 5 with increments of 0.1\n",
"# Define an array of x values from -5 to 5 with increments of 0.01\n",
"x = np.arange(0.01,5.0, 0.01)\n",
"y = np.log(x) ;\n",
"\n",

6
Notebooks/Chap02/2_1_Supervised_Learning.ipynb
View File

@@ -31,7 +31,7 @@
"source": [
"# Notebook 2.1 Supervised Learning\n",
"\n",
"The purpose of this notebook is to explore the linear regression model dicussed in Chapter 2 of the book.\n",
"The purpose of this notebook is to explore the linear regression model discussed in Chapter 2 of the book.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and write code to complete the functions. There are also questions interspersed in the text.\n",
"\n",
@@ -213,7 +213,7 @@
"\n",
"# Make a 2D array for the losses\n",
"all_losses = np.zeros_like(phi1_mesh)\n",
"# Run throught each 2D combination of phi0, phi1 and compute loss\n",
"# Run through each 2D combination of phi0, phi1 and compute loss\n",
"for indices,temp in np.ndenumerate(phi1_mesh):\n",
" all_losses[indices] = compute_loss(x,y, phi0_mesh[indices], phi1_mesh[indices])\n"
],
@@ -250,4 +250,4 @@
"outputs": []
}
]
}
}

10
Notebooks/Chap03/3_1_Shallow_Networks_I.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyM+98aMABiK5vNFFYAwiPiL",
"authorship_tag": "ABX9TyPBNztJrxnUt1ELWfm1Awa3",
"include_colab_link": true
},
"kernelspec": {
@@ -97,7 +97,7 @@
"ax.set_xlim([-5,5]);ax.set_ylim([-5,5])\n",
"ax.set_xlabel('z'); ax.set_ylabel('ReLU[z]')\n",
"ax.set_aspect('equal')\n",
"plt.show"
"plt.show()"
],
"metadata": {
"id": "okwJmSw9pVNF"
@@ -226,7 +226,7 @@
"source": [
"Now let's play with the parameters to make sure we understand how they work. The original parameters were:\n",
"\n",
"$\\theta_{10} = 0.3$ ; $\\theta_{20} = -1.0$<br>\n",
"$\\theta_{10} = 0.3$ ; $\\theta_{11} = -1.0$<br>\n",
"$\\theta_{20} = -1.0$ ; $\\theta_{21} = 2.0$<br>\n",
"$\\theta_{30} = -0.5$ ; $\\theta_{31} = 0.65$<br>\n",
"$\\phi_0 = -0.3; \\phi_1 = 2.0; \\phi_2 = -1.0; \\phi_3 = 7.0$"
@@ -347,7 +347,7 @@
"\n",
"# Compute the least squares loss and print it out\n",
"loss = least_squares_loss(y_train,y_predict)\n",
"print(\"Loss = %3.3f\"%(loss))\n",
"print("Your Loss = %3.3f, True value = 9.385"%(loss))\n",
"\n",
"# TODO. Manipulate the parameters (by hand!) to make the function\n",
"# fit the data better and try to reduce the loss to as small a number\n",
@@ -362,4 +362,4 @@
"outputs": []
}
]
}
}

2
Notebooks/Chap03/3_2_Shallow_Networks_II.ipynb
View File

@@ -182,7 +182,7 @@
{
"cell_type": "markdown",
"source": [
"Now we'll extend this model to have two outputs $y_1$ and $y_2$, each of which can be visualized with a separate heatmap. You will now have sets of parameters $\\phi_{10}, \\phi_{11},\\phi_{12}$ and $\\phi_{20}, \\phi_{21},\\phi_{22}$ that correspond to each of these outputs."
"Now we'll extend this model to have two outputs $y_1$ and $y_2$, each of which can be visualized with a separate heatmap. You will now have sets of parameters $\\phi_{10}, \\phi_{11}, \\phi_{12}$, $\\phi_{13} and $\\phi_{20}, \\phi_{21}, \\phi_{22}$, \\phi_{23}$ that correspond to each of these outputs."
],
"metadata": {
"id": "Xl6LcrUyM7Lh"

10
Notebooks/Chap03/3_3_Shallow_Network_Regions.ipynb
View File

@@ -48,7 +48,7 @@
"import numpy as np\n",
"# Imports plotting library\n",
"import matplotlib.pyplot as plt\n",
"# Imports math libray\n",
"# Imports math library\n",
"import math"
],
"metadata": {
@@ -79,7 +79,7 @@
"source": [
"def number_regions(Di, D):\n",
" # TODO -- implement Zaslavsky's formula\n",
" # You can use math.com() https://www.w3schools.com/python/ref_math_comb.asp\n",
" # You can use math.comb() https://www.w3schools.com/python/ref_math_comb.asp\n",
" # Replace this code\n",
" N = 1;\n",
"\n",
@@ -102,7 +102,7 @@
{
"cell_type": "code",
"source": [
"# Calculate the number of regions for 10D input (Di=2) and 50 hidden units (D=50)\n",
"# Calculate the number of regions for 10D input (Di=10) and 50 hidden units (D=50)\n",
"N = number_regions(10, 50)\n",
"print(f\"Di=10, D=50, Number of regions = {int(N)}, True value = 13432735556\")"
],
@@ -126,7 +126,7 @@
{
"cell_type": "code",
"source": [
"# Show that calculation fails when $D_i < D$\n",
"# Depending on how you implemented it, the calculation may fail when $D_i > D$ (not to worry...)\n",
"try:\n",
" N = number_regions(10, 8)\n",
" print(f\"Di=10, D=8, Number of regions = {int(N)}, True value = 256\")\n",
@@ -256,4 +256,4 @@
"outputs": []
}
]
}
}

6
Notebooks/Chap03/3_4_Activation_Functions.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPmra+JD+dm2M3gCqx3bMak",
"authorship_tag": "ABX9TyOmxhh3ymYWX+1HdZ91I6zU",
"include_colab_link": true
},
"kernelspec": {
@@ -223,7 +223,7 @@
"ax.plot(z,sig_z,'r-')\n",
"ax.set_xlim([-1,1]);ax.set_ylim([0,1])\n",
"ax.set_xlabel('z'); ax.set_ylabel('sig[z]')\n",
"plt.show"
"plt.show()"
],
"metadata": {
"id": "94HIXKJH97ve"
@@ -318,7 +318,7 @@
"ax.plot(z,heav_z,'r-')\n",
"ax.set_xlim([-1,1]);ax.set_ylim([-2,2])\n",
"ax.set_xlabel('z'); ax.set_ylabel('heaviside[z]')\n",
"plt.show"
"plt.show()"
],
"metadata": {
"id": "mSPyp7iA-44H"

7
Notebooks/Chap04/4_3_Deep_Networks.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPyaqr0yJlxfIcTpfLSHDrP",
"authorship_tag": "ABX9TyO2DaD75p+LGi7WgvTzjrk1",
"include_colab_link": true
},
"kernelspec": {
@@ -101,7 +101,6 @@
"cell_type": "code",
"source": [
"# # Plot the shallow neural network. We'll assume input in is range [-1,1] and output [-1,1]\n",
"# If the plot_all flag is set to true, then we'll plot all the intermediate stages as in Figure 3.3\n",
"def plot_neural(x, y):\n",
" fig, ax = plt.subplots()\n",
" ax.plot(x.T,y.T)\n",
@@ -232,7 +231,7 @@
"beta_2 = np.zeros((1,1))\n",
"Omega_2 = np.zeros((1,3))\n",
"\n",
"# TODO Fill in the values of the beta and Omega matrices for with the n1_theta, n1_phi, n2_theta, and n2_phi parameters\n",
"# TODO Fill in the values of the beta and Omega matrices for the n1_theta, n1_phi, n2_theta, and n2_phi parameters\n",
"# that define the composition of the two networks above (see eqn 4.5 for Omega1 and beta1 albeit in different notation)\n",
"# !!! NOTE THAT MATRICES ARE CONVENTIONALLY INDEXED WITH a_11 IN THE TOP LEFT CORNER, BUT NDARRAYS START AT [0,0] SO EVERYTHING IS OFFSET\n",
"# To get you started I've filled in a few:\n",
@@ -319,4 +318,4 @@
"outputs": []
}
]
}
}

75
Notebooks/Chap05/5_1_Least_Squares_Loss.ipynb
View File

@@ -4,7 +4,6 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPX88BLalmJTle9GSAZMJcz",
"include_colab_link": true
},
"kernelspec": {
@@ -66,7 +65,7 @@
" return activation\n",
"\n",
"# Define a shallow neural network\n",
"def shallow_nn(x, beta_0, omega_0, beta_1, omaga_1):\n",
"def shallow_nn(x, beta_0, omega_0, beta_1, omega_1):\n",
" # Make sure that input data is (1 x n_data) array\n",
" n_data = x.size\n",
" x = np.reshape(x,(1,n_data))\n",
@@ -139,7 +138,7 @@
"source": [
"# Univariate regression\n",
"\n",
"We'll investigate a simple univarite regression situation with a single input $x$ and a single output $y$ as pictured in figures 5.4 and 5.5b."
"We'll investigate a simple univariate regression situation with a single input $x$ and a single output $y$ as pictured in figures 5.4 and 5.5b."
],
"metadata": {
"id": "PsgLZwsPxauP"
@@ -306,7 +305,8 @@
"source": [
"# Return the negative log likelihood of the data under the model\n",
"def compute_negative_log_likelihood(y_train, mu, sigma):\n",
" # TODO -- compute the likelihood of the data -- don't use the likelihood function above -- compute the negative sum of the log probabilities\n",
" # TODO -- compute the negative log likelihood of the data without using a product\n",
" # In other words, compute minus one times the sum of the log probabilities\n",
" # Equation 5.4 in the notes\n",
" # You will need np.sum(), np.log()\n",
" # Replace the line below\n",
@@ -352,7 +352,7 @@
{
"cell_type": "code",
"source": [
"# Return the squared distance between the predicted\n",
"# Return the squared distance between the observed data (y_train) and the prediction of the model (y_pred)\n",
"def compute_sum_of_squares(y_train, y_pred):\n",
" # TODO -- compute the sum of squared distances between the training data and the model prediction\n",
" # Eqn 5.10 in the notes. Make sure that you understand this, and ask questions if you don't\n",
@@ -372,9 +372,9 @@
"source": [
"# Let's test this again\n",
"beta_0, omega_0, beta_1, omega_1 = get_parameters()\n",
"# Use our neural network to predict the mean of the Gaussian\n",
"y_pred = shallow_nn(x_train, beta_0, omega_0, beta_1, omega_1)\n",
"# Compute the log likelihood\n",
"# Use our neural network to predict the mean of the Gaussian, which is out best prediction of y\n",
"y_pred = mu_pred = shallow_nn(x_train, beta_0, omega_0, beta_1, omega_1)\n",
"# Compute the sum of squares\n",
"sum_of_squares = compute_sum_of_squares(y_train, y_pred)\n",
"# Let's double check we get the right answer before proceeding\n",
"print(\"Correct answer = %9.9f, Your answer = %9.9f\"%(2.020992572,sum_of_squares))"
@@ -432,12 +432,25 @@
"cell_type": "code",
"source": [
"# Now let's plot the likelihood, negative log likelihood, and least squares as a function the value of the offset beta1\n",
"fig, ax = plt.subplots(1,3)\n",
"fig.set_size_inches(10.5, 3.5)\n",
"fig.tight_layout(pad=3.0)\n",
"ax[0].plot(beta_1_vals, likelihoods); ax[0].set_xlabel('beta_1[0]$'); ax[0].set_ylabel('likelihood')\n",
"ax[1].plot(beta_1_vals, nlls); ax[1].set_xlabel('beta_1[0]'); ax[1].set_ylabel('negative log likelihood')\n",
"ax[2].plot(beta_1_vals, sum_squares); ax[2].set_xlabel('beta_1[0]'); ax[2].set_ylabel('sum of squares')\n",
"fig, ax = plt.subplots(1,2)\n",
"fig.set_size_inches(10.5, 5.5)\n",
"fig.tight_layout(pad=10.0)\n",
"likelihood_color = 'tab:red'\n",
"nll_color = 'tab:blue'\n",
"\n",
"ax[0].set_xlabel('beta_1[0]')\n",
"ax[0].set_ylabel('likelihood', color = likelihood_color)\n",
"ax[0].plot(beta_1_vals, likelihoods, color = likelihood_color)\n",
"ax[0].tick_params(axis='y', labelcolor=likelihood_color)\n",
"\n",
"ax00 = ax[0].twinx()\n",
"ax00.plot(beta_1_vals, nlls, color = nll_color)\n",
"ax00.set_ylabel('negative log likelihood', color = nll_color)\n",
"ax00.tick_params(axis='y', labelcolor = nll_color)\n",
"\n",
"plt.axvline(x = beta_1_vals[np.argmax(likelihoods)], linestyle='dotted')\n",
"\n",
"ax[1].plot(beta_1_vals, sum_squares); ax[1].set_xlabel('beta_1[0]'); ax[1].set_ylabel('sum of squares')\n",
"plt.show()"
],
"metadata": {
@@ -518,12 +531,26 @@
"cell_type": "code",
"source": [
"# Now let's plot the likelihood, negative log likelihood, and least squares as a function the value of the standard divation sigma\n",
"fig, ax = plt.subplots(1,3)\n",
"fig.set_size_inches(10.5, 3.5)\n",
"fig.tight_layout(pad=3.0)\n",
"ax[0].plot(sigma_vals, likelihoods); ax[0].set_xlabel('$\\sigma$'); ax[0].set_ylabel('likelihood')\n",
"ax[1].plot(sigma_vals, nlls); ax[1].set_xlabel('$\\sigma$'); ax[1].set_ylabel('negative log likelihood')\n",
"ax[2].plot(sigma_vals, sum_squares); ax[2].set_xlabel('$\\sigma$'); ax[2].set_ylabel('sum of squares')\n",
"fig, ax = plt.subplots(1,2)\n",
"fig.set_size_inches(10.5, 5.5)\n",
"fig.tight_layout(pad=10.0)\n",
"likelihood_color = 'tab:red'\n",
"nll_color = 'tab:blue'\n",
"\n",
"\n",
"ax[0].set_xlabel('sigma')\n",
"ax[0].set_ylabel('likelihood', color = likelihood_color)\n",
"ax[0].plot(sigma_vals, likelihoods, color = likelihood_color)\n",
"ax[0].tick_params(axis='y', labelcolor=likelihood_color)\n",
"\n",
"ax00 = ax[0].twinx()\n",
"ax00.plot(sigma_vals, nlls, color = nll_color)\n",
"ax00.set_ylabel('negative log likelihood', color = nll_color)\n",
"ax00.tick_params(axis='y', labelcolor = nll_color)\n",
"\n",
"plt.axvline(x = sigma_vals[np.argmax(likelihoods)], linestyle='dotted')\n",
"\n",
"ax[1].plot(sigma_vals, sum_squares); ax[1].set_xlabel('sigma'); ax[1].set_ylabel('sum of squares')\n",
"plt.show()"
],
"metadata": {
@@ -538,8 +565,8 @@
"# Hopefully, you can see that the maximum of the likelihood fn is at the same position as the minimum negative log likelihood\n",
"# The least squares solution does not depend on sigma, so it's just flat -- no use here.\n",
"# Let's check that:\n",
"print(\"Maximum likelihood = %3.3f, at beta_1=%3.3f\"%( (likelihoods[np.argmax(likelihoods)],sigma_vals[np.argmax(likelihoods)])))\n",
"print(\"Minimum negative log likelihood = %3.3f, at beta_1=%3.3f\"%( (nlls[np.argmin(nlls)],sigma_vals[np.argmin(nlls)])))\n",
"print(\"Maximum likelihood = %3.3f, at sigma=%3.3f\"%( (likelihoods[np.argmax(likelihoods)],sigma_vals[np.argmax(likelihoods)])))\n",
"print(\"Minimum negative log likelihood = %3.3f, at sigma=%3.3f\"%( (nlls[np.argmin(nlls)],sigma_vals[np.argmin(nlls)])))\n",
"# Plot the best model\n",
"sigma= sigma_vals[np.argmin(nlls)]\n",
"y_model = shallow_nn(x_model, beta_0, omega_0, beta_1, omega_1)\n",
@@ -554,7 +581,7 @@
{
"cell_type": "markdown",
"source": [
"Obviously, to fit the full neural model we would vary all of the 10 parameters of the network in the $\\boldsymbol\\beta_{0},\\boldsymbol\\omega_{0},\\boldsymbol\\beta_{1},\\boldsymbol\\omega_{1}$ (and maybe $\\sigma$) until we find the combination that have the maximum likelihood / minimum negative log likelihood / least squares.<br><br>\n",
"Obviously, to fit the full neural model we would vary all of the 10 parameters of the network in $\\boldsymbol\\beta_{0},\\boldsymbol\\omega_{0},\\boldsymbol\\beta_{1},\\boldsymbol\\omega_{1}$ (and maybe $\\sigma$) until we find the combination that have the maximum likelihood / minimum negative log likelihood / least squares.<br><br>\n",
"\n",
"Here we just varied one at a time as it is easier to see what is going on. This is known as **coordinate descent**.\n"
],
@@ -563,4 +590,4 @@
}
}
]
}
}

27
Notebooks/Chap05/5_2_Binary_Cross_Entropy_Loss.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOlPP7m+YTLyMPaN0WxRdrb",
"authorship_tag": "ABX9TyOSb+W2AOFVQm8FZcHAb2Jq",
"include_colab_link": true
},
"kernelspec": {
@@ -378,12 +378,25 @@
{
"cell_type": "code",
"source": [
"# Now let's plot the likelihood, and negative log likelihoods as a function the value of the offset beta1\n",
"fig, ax = plt.subplots(1,2)\n",
"fig.set_size_inches(10.5, 3.5)\n",
"fig.tight_layout(pad=3.0)\n",
"ax[0].plot(beta_1_vals, likelihoods); ax[0].set_xlabel('beta_1[0]'); ax[0].set_ylabel('likelihood')\n",
"ax[1].plot(beta_1_vals, nlls); ax[1].set_xlabel('beta_1[0]'); ax[1].set_ylabel('negative log likelihood')\n",
"# Now let's plot the likelihood, negative log likelihood, and least squares as a function the value of the offset beta1\n",
"fig, ax = plt.subplots()\n",
"fig.tight_layout(pad=5.0)\n",
"likelihood_color = 'tab:red'\n",
"nll_color = 'tab:blue'\n",
"\n",
"\n",
"ax.set_xlabel('beta_1[0]')\n",
"ax.set_ylabel('likelihood', color = likelihood_color)\n",
"ax.plot(beta_1_vals, likelihoods, color = likelihood_color)\n",
"ax.tick_params(axis='y', labelcolor=likelihood_color)\n",
"\n",
"ax1 = ax.twinx()\n",
"ax1.plot(beta_1_vals, nlls, color = nll_color)\n",
"ax1.set_ylabel('negative log likelihood', color = nll_color)\n",
"ax1.tick_params(axis='y', labelcolor = nll_color)\n",
"\n",
"plt.axvline(x = beta_1_vals[np.argmax(likelihoods)], linestyle='dotted')\n",
"\n",
"plt.show()"
],
"metadata": {

29
Notebooks/Chap05/5_3_Multiclass_Cross_entropy_Loss.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOVTohDBtmCCzSEqLJ4J9R/",
"authorship_tag": "ABX9TyOPv/l+ToaApJV7Nz+8AtpV",
"include_colab_link": true
},
"kernelspec": {
@@ -68,7 +68,7 @@
" return activation\n",
"\n",
"# Define a shallow neural network\n",
"def shallow_nn(x, beta_0, omega_0, beta_1, omaga_1):\n",
"def shallow_nn(x, beta_0, omega_0, beta_1, omega_1):\n",
" # Make sure that input data is (1 x n_data) array\n",
" n_data = x.size\n",
" x = np.reshape(x,(1,n_data))\n",
@@ -401,12 +401,25 @@
{
"cell_type": "code",
"source": [
"# Now let's plot the likelihood, negative log likelihood as a function the value of the offset beta1\n",
"fig, ax = plt.subplots(1,2)\n",
"fig.set_size_inches(10.5, 3.5)\n",
"fig.tight_layout(pad=3.0)\n",
"ax[0].plot(beta_1_vals, likelihoods); ax[0].set_xlabel('beta_1[0,0]'); ax[0].set_ylabel('likelihood')\n",
"ax[1].plot(beta_1_vals, nlls); ax[1].set_xlabel('beta_1[0,0]'); ax[1].set_ylabel('negative log likelihood')\n",
"# Now let's plot the likelihood, negative log likelihood, and least squares as a function the value of the offset beta1\n",
"fig, ax = plt.subplots()\n",
"fig.tight_layout(pad=5.0)\n",
"likelihood_color = 'tab:red'\n",
"nll_color = 'tab:blue'\n",
"\n",
"\n",
"ax.set_xlabel('beta_1[0, 0]')\n",
"ax.set_ylabel('likelihood', color = likelihood_color)\n",
"ax.plot(beta_1_vals, likelihoods, color = likelihood_color)\n",
"ax.tick_params(axis='y', labelcolor=likelihood_color)\n",
"\n",
"ax1 = ax.twinx()\n",
"ax1.plot(beta_1_vals, nlls, color = nll_color)\n",
"ax1.set_ylabel('negative log likelihood', color = nll_color)\n",
"ax1.tick_params(axis='y', labelcolor = nll_color)\n",
"\n",
"plt.axvline(x = beta_1_vals[np.argmax(likelihoods)], linestyle='dotted')\n",
"\n",
"plt.show()"
],
"metadata": {

9
Notebooks/Chap06/6_1_Line_Search.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOfxeJ15PMkIi4geDTRCz3c",
"authorship_tag": "ABX9TyN4E9Vtuk6t2BhZ0Ajv5SW3",
"include_colab_link": true
},
"kernelspec": {
@@ -131,14 +131,15 @@
"\n",
" print('Iter %d, a=%3.3f, b=%3.3f, c=%3.3f, d=%3.3f'%(n_iter, a,b,c,d))\n",
"\n",
" # Rule #1 If point A is less than points B, C, and D then halve values of B, C, and D\n",
" # Rule #1 If the HEIGHT at point A is less the HEIGHT at points B, C, and D then halve values of B, C, and D\n",
" # i.e. bring them closer to the original point\n",
" # i.e. bring them closer to the original point\n",
" # TODO REPLACE THE BLOCK OF CODE BELOW WITH THIS RULE\n",
" if (0):\n",
" continue;\n",
"\n",
"\n",
" # Rule #2 If point b is less than point c then\n",
" # Rule #2 If the HEIGHT at point b is less than the HEIGHT at point c then\n",
" # then point d becomes point c, and\n",
" # point b becomes 1/3 between a and new d\n",
" # point c becomes 2/3 between a and new d\n",
@@ -146,7 +147,7 @@
" if (0):\n",
" continue;\n",
"\n",
" # Rule #3 If point c is less than point b then\n",
" # Rule #3 If the HEIGHT at point c is less than the HEIGHT at point b then\n",
" # then point a becomes point b, and\n",
" # point b becomes 1/3 between new a and d\n",
" # point c becomes 2/3 between new a and d\n",

17
Notebooks/Chap06/6_2_Gradient_Descent.ipynb
View File

@@ -4,7 +4,6 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyM/FIXDTd6tZYs6WRzK00hB",
"include_colab_link": true
},
"kernelspec": {
@@ -31,7 +30,7 @@
"source": [
"# **Notebook 6.2 Gradient descent**\n",
"\n",
"This notebook recreates the gradient descent algorithm as shon in figure 6.1.\n",
"This notebook recreates the gradient descent algorithm as shown in figure 6.1.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
@@ -301,7 +300,7 @@
{
"cell_type": "markdown",
"source": [
"Now we are ready to perform gradient descent. We'll need to use our line search routine from part I, which I've reproduced here plus the helper function loss_function_1D that converts from a 2D problem to a 1D problem"
"Now we are ready to perform gradient descent. We'll need to use our line search routine from notebook 6.1, which I've reproduced here plus the helper function loss_function_1D that maps the search along the negative gradient direction in 2D space to a 1D problem (distance along this direction)"
],
"metadata": {
"id": "5EIjMM9Fw2eT"
@@ -310,9 +309,9 @@
{
"cell_type": "code",
"source": [
"def loss_function_1D(dist_prop, data, model, phi_start, gradient):\n",
"def loss_function_1D(dist_prop, data, model, phi_start, search_direction):\n",
" # Return the loss after moving this far\n",
" return compute_loss(data[0,:], data[1,:], model, phi_start+ gradient * dist_prop)\n",
" return compute_loss(data[0,:], data[1,:], model, phi_start+ search_direction * dist_prop)\n",
"\n",
"def line_search(data, model, phi, gradient, thresh=.00001, max_dist = 0.1, max_iter = 15, verbose=False):\n",
" # Initialize four points along the range we are going to search\n",
@@ -375,9 +374,9 @@
"source": [
"def gradient_descent_step(phi, data, model):\n",
" # TODO -- update Phi with the gradient descent step (equation 6.3)\n",
" # 1. Compute the gradient\n",
" # 2. Find the best step size alpha (use negative gradient as going downhill)\n",
" # 3. Update the parameters phi\n",
" # 1. Compute the gradient (you wrote this function above)\n",
" # 2. Find the best step size alpha using line search function (above) -- use negative gradient as going downhill\n",
" # 3. Update the parameters phi based on the gradient and the step size alpha.\n",
"\n",
" return phi"
],
@@ -418,4 +417,4 @@
"outputs": []
}
]
}
}

6
Notebooks/Chap06/6_3_Stochastic_Gradient_Descent.ipynb
View File

@@ -123,7 +123,7 @@
{
"cell_type": "code",
"source": [
"# Initialize the parmaeters and draw the model\n",
"# Initialize the parameters and draw the model\n",
"phi = np.zeros((2,1))\n",
"phi[0] = -5 # Horizontal offset\n",
"phi[1] = 25 # Frequency\n",
@@ -518,7 +518,7 @@
" # at each step\n",
" # You can use the function np.random.permutation to generate a random permutation of the n_data = data.shape[1] indices\n",
" # and then just choose the first n=batch_size of these indices. Then compute the gradient update\n",
" # from just the data with these indices. More properly, you should sample with replacement, but this will do for now.\n",
" # from just the data with these indices. More properly, you should sample without replacement, but this will do for now.\n",
"\n",
"\n",
" return phi"
@@ -583,4 +583,4 @@
"outputs": []
}
]
}
}

12
Notebooks/Chap06/6_4_Momentum.ipynb
View File

@@ -4,7 +4,6 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyMLS4qeqBTVHGdg9Sds9jND",
"include_colab_link": true
},
"kernelspec": {
@@ -123,7 +122,7 @@
{
"cell_type": "code",
"source": [
"# Initialize the parmaeters and draw the model\n",
"# Initialize the parameters and draw the model\n",
"phi = np.zeros((2,1))\n",
"phi[0] = -5 # Horizontal offset\n",
"phi[1] = 25 # Frequency\n",
@@ -377,6 +376,15 @@
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Note that for this case, Nesterov momentum does not improve the result."
],
"metadata": {
"id": "F-As4hS8s2nm"
}
}
]
}

2
Notebooks/Chap06/6_5_Adam.ipynb
View File

@@ -248,7 +248,7 @@
" # Replace this line:\n",
" v = v\n",
"\n",
" # TODO -- Modify the statistics according to euation 6.16\n",
" # TODO -- Modify the statistics according to equation 6.16\n",
" # You will need the function np.power\n",
" # Replace these lines\n",
" m_tilde = m\n",

136
Notebooks/Chap07/7_1_Backpropagation_in_Toy_Model.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyP5wHK5E7/el+vxU947K3q8",
"authorship_tag": "ABX9TyOjXmTmoff61y15VqEB5sDW",
"include_colab_link": true
},
"kernelspec": {
@@ -83,13 +83,13 @@
"metadata": {
"id": "RIPaoVN834Lj"
},
"execution_count": null,
"execution_count": 1,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Let's first define the original function for $y$ and the likelihood term:"
"Let's first define the original function for $y$ and the loss term:"
],
"metadata": {
"id": "32-ufWhc3v2c"
@@ -97,7 +97,7 @@
},
{
"cell_type": "code",
"execution_count": null,
"execution_count": 2,
"metadata": {
"id": "AakK_qen3BpU"
},
@@ -106,7 +106,7 @@
"def fn(x, beta0, beta1, beta2, beta3, omega0, omega1, omega2, omega3):\n",
" return beta3+omega3 * np.cos(beta2 + omega2 * np.exp(beta1 + omega1 * np.sin(beta0 + omega0 * x)))\n",
"\n",
"def likelihood(x, y, beta0, beta1, beta2, beta3, omega0, omega1, omega2, omega3):\n",
"def loss(x, y, beta0, beta1, beta2, beta3, omega0, omega1, omega2, omega3):\n",
" diff = fn(x, beta0, beta1, beta2, beta3, omega0, omega1, omega2, omega3) - y\n",
" return diff * diff"
]
@@ -126,14 +126,26 @@
"beta0 = 1.0; beta1 = 2.0; beta2 = -3.0; beta3 = 0.4\n",
"omega0 = 0.1; omega1 = -0.4; omega2 = 2.0; omega3 = 3.0\n",
"x = 2.3; y =2.0\n",
"l_i_func = likelihood(x,y,beta0,beta1,beta2,beta3,omega0,omega1,omega2,omega3)\n",
"l_i_func = loss(x,y,beta0,beta1,beta2,beta3,omega0,omega1,omega2,omega3)\n",
"print('l_i=%3.3f'%l_i_func)"
],
"metadata": {
"id": "pwvOcCxr41X_"
"id": "pwvOcCxr41X_",
"colab": {
"base_uri": "https://localhost:8080/"
},
"outputId": "9541922c-dfc4-4b2e-dfa3-3298812155ce"
},
"execution_count": null,
"outputs": []
"execution_count": 3,
"outputs": [
{
"output_type": "stream",
"name": "stdout",
"text": [
"l_i=0.139\n"
]
}
]
},
{
"cell_type": "markdown",
@@ -163,7 +175,7 @@
"metadata": {
"id": "7t22hALp5zkq"
},
"execution_count": null,
"execution_count": 4,
"outputs": []
},
{
@@ -178,15 +190,27 @@
{
"cell_type": "code",
"source": [
"dldomega0_fd = (likelihood(x,y,beta0,beta1,beta2,beta3,omega0+0.00001,omega1,omega2,omega3)-likelihood(x,y,beta0,beta1,beta2,beta3,omega0,omega1,omega2,omega3))/0.00001\n",
"dldomega0_fd = (loss(x,y,beta0,beta1,beta2,beta3,omega0+0.00001,omega1,omega2,omega3)-loss(x,y,beta0,beta1,beta2,beta3,omega0,omega1,omega2,omega3))/0.00001\n",
"\n",
"print('dydomega0: Function value = %3.3f, Finite difference value = %3.3f'%(dldomega0_func,dldomega0_fd))"
],
"metadata": {
"id": "1O3XmXMx-HlZ"
"id": "1O3XmXMx-HlZ",
"colab": {
"base_uri": "https://localhost:8080/"
},
"outputId": "389ed78e-9d8d-4e8b-9e6b-5f20c21407e8"
},
"execution_count": null,
"outputs": []
"execution_count": 5,
"outputs": [
{
"output_type": "stream",
"name": "stdout",
"text": [
"dydomega0: Function value = 5.246, Finite difference value = 5.246\n"
]
}
]
},
{
"cell_type": "markdown",
@@ -237,7 +261,7 @@
"metadata": {
"id": "ZWKAq6HC90qV"
},
"execution_count": null,
"execution_count": 6,
"outputs": []
},
{
@@ -254,15 +278,34 @@
"print(\"like original = %3.3f, like from forward pass = %3.3f\"%(l_i_func, l_i))\n"
],
"metadata": {
"id": "ibxXw7TUW4Sx"
"id": "ibxXw7TUW4Sx",
"colab": {
"base_uri": "https://localhost:8080/"
},
"outputId": "4575e3eb-2b16-4e0b-c84e-9c22b443c3ce"
},
"execution_count": null,
"outputs": []
"execution_count": 7,
"outputs": [
{
"output_type": "stream",
"name": "stdout",
"text": [
"f0: true value = 1.230, your value = 0.000\n",
"h1: true value = 0.942, your value = 0.000\n",
"f1: true value = 1.623, your value = 0.000\n",
"h2: true value = 5.068, your value = 0.000\n",
"f2: true value = 7.137, your value = 0.000\n",
"h3: true value = 0.657, your value = 0.000\n",
"f3: true value = 2.372, your value = 0.000\n",
"like original = 0.139, like from forward pass = 0.000\n"
]
}
]
},
{
"cell_type": "markdown",
"source": [
"**Step 2:** Compute the derivatives of $y$ with respect to the intermediate quantities that we just calculated, but in reverse order:\n",
"**Step 2:** Compute the derivatives of $\\ell_i$ with respect to the intermediate quantities that we just calculated, but in reverse order:\n",
"\n",
"\\begin{eqnarray}\n",
"\\quad \\frac{\\partial \\ell_i}{\\partial f_3}, \\quad \\frac{\\partial \\ell_i}{\\partial h_3}, \\quad \\frac{\\partial \\ell_i}{\\partial f_2}, \\quad\n",
@@ -281,7 +324,7 @@
"\\frac{\\partial \\ell_i}{\\partial h_{3}} =\\frac{\\partial f_{3}}{\\partial h_{3}} \\frac{\\partial \\ell_i}{\\partial f_{3}} .\n",
"\\end{equation}\n",
"\n",
"The left-hand side asks how $\\ell_i$ changes when $h_{3}$ changes. The right-hand side says we can decompose this into (i) how $ell_i$ changes when $f_{3}$ changes and how $f_{3}$ changes when $h_{3}$ changes. So you get a chain of events happening: $h_{3}$ changes $f_{3}$, which changes $\\ell_i$, and the derivatives represent the effects of this chain. Notice that we computed the first of these derivatives already and is $2 (f_3-y)$. We calculated $f_{3}$ in step 1. The second term is the derivative of $\\beta_{3} + \\omega_{3}h_{3}$ with respect to $h_3$ which is simply $\\omega_3$. \n",
"The left-hand side asks how $\\ell_i$ changes when $h_{3}$ changes. The right-hand side says we can decompose this into (i) how $\\ell_i$ changes when $f_{3}$ changes and how $f_{3}$ changes when $h_{3}$ changes. So you get a chain of events happening: $h_{3}$ changes $f_{3}$, which changes $\\ell_i$, and the derivatives represent the effects of this chain. Notice that we computed the first of these derivatives already and is $2 (f_3-y)$. We calculated $f_{3}$ in step 1. The second term is the derivative of $\\beta_{3} + \\omega_{3}h_{3}$ with respect to $h_3$ which is simply $\\omega_3$. \n",
"\n",
"We can continue in this way, computing the derivatives of the output with respect to these intermediate quantities:\n",
"\n",
@@ -319,7 +362,7 @@
"metadata": {
"id": "gCQJeI--Egdl"
},
"execution_count": null,
"execution_count": 8,
"outputs": []
},
{
@@ -335,10 +378,28 @@
"print(\"dldf0: true value = %3.3f, your value = %3.3f\"%(2.281, dldf0))"
],
"metadata": {
"id": "dS1OrLtlaFr7"
"id": "dS1OrLtlaFr7",
"colab": {
"base_uri": "https://localhost:8080/"
},
"outputId": "414f0862-ae36-4a0e-b68f-4758835b0e23"
},
"execution_count": null,
"outputs": []
"execution_count": 9,
"outputs": [
{
"output_type": "stream",
"name": "stdout",
"text": [
"dldf3: true value = 0.745, your value = -4.000\n",
"dldh3: true value = 2.234, your value = -12.000\n",
"dldf2: true value = -1.683, your value = 1.000\n",
"dldh2: true value = -3.366, your value = 1.000\n",
"dldf1: true value = -17.060, your value = 1.000\n",
"dldh1: true value = 6.824, your value = 1.000\n",
"dldf0: true value = 2.281, your value = 1.000\n"
]
}
]
},
{
"cell_type": "markdown",
@@ -380,7 +441,7 @@
"metadata": {
"id": "1I2BhqZhGMK6"
},
"execution_count": null,
"execution_count": 10,
"outputs": []
},
{
@@ -397,10 +458,29 @@
"print('dldomega0: Your value = %3.3f, Function value = %3.3f, Finite difference value = %3.3f'%(dldomega0, dldomega0_func, dldomega0_fd))"
],
"metadata": {
"id": "38eiOn2aHgHI"
"id": "38eiOn2aHgHI",
"colab": {
"base_uri": "https://localhost:8080/"
},
"outputId": "1a67a636-e832-471e-e771-54824363158a"
},
"execution_count": null,
"outputs": []
"execution_count": 11,
"outputs": [
{
"output_type": "stream",
"name": "stdout",
"text": [
"dldbeta3: Your value = 1.000, True value = 0.745\n",
"dldomega3: Your value = 1.000, True value = 0.489\n",
"dldbeta2: Your value = 1.000, True value = -1.683\n",
"dldomega2: Your value = 1.000, True value = -8.530\n",
"dldbeta1: Your value = 1.000, True value = -17.060\n",
"dldomega1: Your value = 1.000, True value = -16.079\n",
"dldbeta0: Your value = 1.000, True value = 2.281\n",
"dldomega0: Your value = 1.000, Function value = 5.246, Finite difference value = 5.246\n"
]
}
]
},
{
"cell_type": "markdown",

12
Notebooks/Chap07/7_2_Backpropagation.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyN2nPVR0imZntgj4Oasyvmo",
"authorship_tag": "ABX9TyOlKB4TrCJnt91TnHOrfRSJ",
"include_colab_link": true
},
"kernelspec": {
@@ -244,28 +244,28 @@
" all_dl_dh = [None] * (K+1)\n",
" # Again for convenience we'll stick with the convention that all_h[0] is the net input and all_f[k] in the net output\n",
"\n",
" # Compute derivatives of net output with respect to loss\n",
" # Compute derivatives of the loss with respect to the network output\n",
" all_dl_df[K] = np.array(d_loss_d_output(all_f[K],y))\n",
"\n",
" # Now work backwards through the network\n",
" for layer in range(K,-1,-1):\n",
" # TODO Calculate the derivatives of biases at layer this from all_dl_df[layer]. (eq 7.21)\n",
" # TODO Calculate the derivatives of the loss with respect to the biases at layer this from all_dl_df[layer]. (eq 7.21)\n",
" # NOTE! To take a copy of matrix X, use Z=np.array(X)\n",
" # REPLACE THIS LINE\n",
" all_dl_dbiases[layer] = np.zeros_like(all_biases[layer])\n",
"\n",
" # TODO Calculate the derivatives of weight at layer from all_dl_df[K] and all_h[K] (eq 7.22)\n",
" # TODO Calculate the derivatives of the loss with respect to the weights at layer from all_dl_df[layer] and all_h[layer] (eq 7.22)\n",
" # Don't forget to use np.matmul\n",
" # REPLACE THIS LINE\n",
" all_dl_dweights[layer] = np.zeros_like(all_weights[layer])\n",
"\n",
" # TODO: calculate the derivatives of activations from weight and derivatives of next preactivations (eq 7.20)\n",
" # TODO: calculate the derivatives of the loss with respect to the activations from weight and derivatives of next preactivations (second part of last line of eq 7.24)\n",
" # REPLACE THIS LINE\n",
" all_dl_dh[layer] = np.zeros_like(all_h[layer])\n",
"\n",
"\n",
" if layer > 0:\n",
" # TODO Calculate the derivatives of the pre-activation f with respect to activation h (deriv of ReLu function)\n",
" # TODO Calculate the derivatives of the loss with respect to the pre-activation f (use deriv of ReLu function, first part of last line of eq. 7.24)\n",
" # REPLACE THIS LINE\n",
" all_dl_df[layer-1] = np.zeros_like(all_f[layer-1])\n",
"\n",

13
Notebooks/Chap08/8_2_Bias_Variance_Trade_Off.ipynb
View File

@@ -4,7 +4,6 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPz1B8kFc21JvGTDwqniloA",
"include_colab_link": true
},
"kernelspec": {
@@ -77,7 +76,7 @@
" for i in range(n_data):\n",
" x[i] = np.random.uniform(i/n_data, (i+1)/n_data, 1)\n",
"\n",
" # y value from running through functoin and adding noise\n",
" # y value from running through function and adding noise\n",
" y = np.ones(n_data)\n",
" for i in range(n_data):\n",
" y[i] = true_function(x[i])\n",
@@ -185,10 +184,8 @@
" if A[i,j] < 0:\n",
" A[i,j] = 0;\n",
"\n",
" ATA = np.matmul(np.transpose(A), A)\n",
" ATAInv = np.linalg.inv(ATA)\n",
" ATAInvAT = np.matmul(ATAInv, np.transpose(A))\n",
" beta_omega = np.matmul(ATAInvAT,y)\n",
" beta_omega = np.linalg.lstsq(A, y, rcond=None)[0]\n",
"\n",
" beta = beta_omega[0]\n",
" omega = beta_omega[1:]\n",
"\n",
@@ -229,7 +226,7 @@
" y_model_all = np.zeros((n_datasets, x_model.shape[0]))\n",
"\n",
" for c_dataset in range(n_datasets):\n",
" # TODO -- Generate n_data x,y, pairs with standard divation sigma_func\n",
" # TODO -- Generate n_data x,y, pairs with standard deviation sigma_func\n",
" # Replace this line\n",
" x_data,y_data = np.zeros([1,n_data]),np.zeros([1,n_data])\n",
"\n",
@@ -316,7 +313,7 @@
"\n",
" # Compute variance -- average of the model variance (average squared deviation of fitted models around mean fitted model)\n",
" variance[c_hidden] = 0\n",
" # Compute bias (average squared deviaton of mean fitted model around true function)\n",
" # Compute bias (average squared deviation of mean fitted model around true function)\n",
" bias[c_hidden] = 0\n",
"\n",
"# Plot the results\n",

4
Notebooks/Chap08/8_4_High_Dimensional_Spaces.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPXPDEQiwNw+kYhWfg4kjz6",
"authorship_tag": "ABX9TyPAKqlf9VxztHXKylyJwqe8",
"include_colab_link": true
},
"kernelspec": {
@@ -145,7 +145,7 @@
"source": [
"def volume_of_hypersphere(diameter, dimensions):\n",
" # Formula given in Problem 8.7 of the book\n",
" # You will need sci.special.gamma()\n",
" # You will need sci.gamma()\n",
" # Check out: https://docs.scipy.org/doc/scipy/reference/generated/scipy.special.gamma.html\n",
" # Also use this value for pi\n",
" pi = np.pi\n",

2
Notebooks/Chap09/9_1_L2_Regularization.ipynb
View File

@@ -120,7 +120,7 @@
{
"cell_type": "code",
"source": [
"# Initialize the parmaeters and draw the model\n",
"# Initialize the parameters and draw the model\n",
"phi = np.zeros((2,1))\n",
"phi[0] = -5 # Horizontal offset\n",
"phi[1] = 25 # Frequency\n",

104
Notebooks/Chap09/9_2_Implicit_Regularization.ipynb
View File

File diff suppressed because one or more lines are too long

4
Notebooks/Chap09/9_3_Ensembling.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyNuR7X+PMWRddy+WQr4gr5f",
"authorship_tag": "ABX9TyOAC7YLEqN5qZhJXqRj+aHB",
"include_colab_link": true
},
"kernelspec": {
@@ -184,7 +184,9 @@
" A = np.ones((n_data, n_hidden+1))\n",
" for i in range(n_data):\n",
" for j in range(1,n_hidden+1):\n",
" # Compute preactivation\n",
" A[i,j] = x[i]-(j-1)/n_hidden\n",
" # Apply the ReLU function\n",
" if A[i,j] < 0:\n",
" A[i,j] = 0;\n",
"\n",

6
Notebooks/Chap09/9_4_Bayesian_Approach.ipynb
View File

@@ -80,7 +80,7 @@
" for i in range(n_data):\n",
" x[i] = np.random.uniform(i/n_data, (i+1)/n_data, 1)\n",
"\n",
" # y value from running through functoin and adding noise\n",
" # y value from running through function and adding noise\n",
" y = np.ones(n_data)\n",
" for i in range(n_data):\n",
" y[i] = true_function(x[i])\n",
@@ -137,7 +137,7 @@
"n_data = 15\n",
"x_data,y_data = generate_data(n_data, sigma_func)\n",
"\n",
"# Plot the functinon, data and uncertainty\n",
"# Plot the function, data and uncertainty\n",
"plot_function(x_func, y_func, x_data, y_data, sigma_func=sigma_func)"
],
"metadata": {
@@ -357,7 +357,7 @@
"\n",
"To compute this, we reformulated the integrand using the relations from appendices\n",
"C.3.3 and C.3.4 as the product of a normal distribution in $\\boldsymbol\\phi$ and a constant with respect\n",
"to $\\boldsymbol\\phi$. The integral of the normal distribution must be one, and so the finnal result is just the constant. This constant is itself a normal distribution in $y^*$. <br>\n",
"to $\\boldsymbol\\phi$. The integral of the normal distribution must be one, and so the final result is just the constant. This constant is itself a normal distribution in $y^*$. <br>\n",
"\n",
"If you feel so inclined you can work through the math of this yourself."
],

8
Notebooks/Chap09/9_5_Augmentation.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyM3wq9CHLjekkIXIgXRxueE",
"authorship_tag": "ABX9TyM38ZVBK4/xaHk5Ys5lF6dN",
"include_colab_link": true
},
"kernelspec": {
@@ -208,14 +208,14 @@
{
"cell_type": "code",
"source": [
"def augment(data_in):\n",
"def augment(input_vector):\n",
" # Create output vector\n",
" data_out = np.zeros_like(data_in)\n",
" data_out = np.zeros_like(input_vector)\n",
"\n",
" # TODO: Shift the input data by a random offset\n",
" # (rotating, so points that would go off the end, are added back to the beginning)\n",
" # Replace this line:\n",
" data_out = np.zeros_like(data_in) ;\n",
" data_out = np.zeros_like(input_vector) ;\n",
"\n",
" # TODO: # Randomly scale the data by a factor drawn from a uniform distribution over [0.8,1.2]\n",
" # Replace this line:\n",

57
Notebooks/Chap10/10_1_1D_Convolution.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyPHUNRkJMI5LujaxIXNV60m",
"authorship_tag": "ABX9TyML7rfAGE4gvmNUEiK5x3PS",
"include_colab_link": true
},
"kernelspec": {
@@ -41,6 +41,17 @@
"id": "el8l05WQEO46"
}
},
{
"cell_type": "markdown",
"source": [
"NOTE!!\n",
"\n",
"If you have the first edition of the printed book, it mistakenly refers to a convolutional filter with no spaces between the elements (i.e. a normal filter without dilation) as having dilation zero. Actually, the convention is (weirdly) that this has dilation one. And when there is one space between the elements, this is dilation two. This notebook reflects the correct convention and so will be out of sync with the printed book. If this is confusing, check the [errata](https://github.com/udlbook/udlbook/blob/main/UDL_Errata.pdf) document."
],
"metadata": {
"id": "ggQrHkFZcUiV"
}
},
{
"cell_type": "code",
"source": [
@@ -50,7 +61,7 @@
"metadata": {
"id": "nw7k5yCtOzoK"
},
"execution_count": null,
"execution_count": 1,
"outputs": []
},
{
@@ -85,10 +96,10 @@
"cell_type": "code",
"source": [
"# Now let's define a zero-padded convolution operation\n",
"# with a convolution kernel size of 3, a stride of 1, and a dilation of 0\n",
"# with a convolution kernel size of 3, a stride of 1, and a dilation of 1\n",
"# as in figure 10.2a-c. Write it yourself, don't call a library routine!\n",
"# Don't forget that Python arrays are indexed from zero, not from 1 as in the book figures\n",
"def conv_3_1_0_zp(x_in, omega):\n",
"def conv_3_1_1_zp(x_in, omega):\n",
" x_out = np.zeros_like(x_in)\n",
" # TODO -- write this function\n",
" # replace this line\n",
@@ -119,7 +130,7 @@
"source": [
"\n",
"omega = [0.33,0.33,0.33]\n",
"h = conv_3_1_0_zp(x, omega)\n",
"h = conv_3_1_1_zp(x, omega)\n",
"\n",
"# Check that you have computed this correctly\n",
"print(f\"Sum of output is {np.sum(h):3.3}, should be 71.1\")\n",
@@ -155,7 +166,7 @@
"source": [
"\n",
"omega = [-0.5,0,0.5]\n",
"h2 = conv_3_1_0_zp(x, omega)\n",
"h2 = conv_3_1_1_zp(x, omega)\n",
"\n",
"# Draw the signal\n",
"fig,ax = plt.subplots()\n",
@@ -187,9 +198,9 @@
"cell_type": "code",
"source": [
"# Now let's define a zero-padded convolution operation\n",
"# with a convolution kernel size of 3, a stride of 2, and a dilation of 0\n",
"# as in figure 10.2a-c. Write it yourself, don't call a library routine!\n",
"def conv_3_2_0_zp(x_in, omega):\n",
"# with a convolution kernel size of 3, a stride of 2, and a dilation of 1\n",
"# as in figure 10.3a-b. Write it yourself, don't call a library routine!\n",
"def conv_3_2_1_zp(x_in, omega):\n",
" x_out = np.zeros(int(np.ceil(len(x_in)/2)))\n",
" # TODO -- write this function\n",
" # replace this line\n",
@@ -209,7 +220,7 @@
"cell_type": "code",
"source": [
"omega = [0.33,0.33,0.33]\n",
"h3 = conv_3_2_0_zp(x, omega)\n",
"h3 = conv_3_2_1_zp(x, omega)\n",
"\n",
"# If you have done this right, the output length should be six and it should\n",
"# contain every other value from the original convolution with stride 1\n",
@@ -226,9 +237,9 @@
"cell_type": "code",
"source": [
"# Now let's define a zero-padded convolution operation\n",
"# with a convolution kernel size of 5, a stride of 1, and a dilation of 0\n",
"# as in figure 10.2a-c. Write it yourself, don't call a library routine!\n",
"def conv_5_1_0_zp(x_in, omega):\n",
"# with a convolution kernel size of 5, a stride of 1, and a dilation of 1\n",
"# as in figure 10.3c. Write it yourself, don't call a library routine!\n",
"def conv_5_1_1_zp(x_in, omega):\n",
" x_out = np.zeros_like(x_in)\n",
" # TODO -- write this function\n",
" # replace this line\n",
@@ -249,7 +260,7 @@
"source": [
"\n",
"omega2 = [0.2, 0.2, 0.2, 0.2, 0.2]\n",
"h4 = conv_5_1_0_zp(x, omega2)\n",
"h4 = conv_5_1_1_zp(x, omega2)\n",
"\n",
"# Check that you have computed this correctly\n",
"print(f\"Sum of output is {np.sum(h4):3.3}, should be 69.6\")\n",
@@ -273,10 +284,10 @@
"cell_type": "code",
"source": [
"# Finally let's define a zero-padded convolution operation\n",
"# with a convolution kernel size of 3, a stride of 1, and a dilation of 1\n",
"# as in figure 10.2a-c. Write it yourself, don't call a library routine!\n",
"# with a convolution kernel size of 3, a stride of 1, and a dilation of 2\n",
"# as in figure 10.3d. Write it yourself, don't call a library routine!\n",
"# Don't forget that Python arrays are indexed from zero, not from 1 as in the book figures\n",
"def conv_3_1_1_zp(x_in, omega):\n",
"def conv_3_1_2_zp(x_in, omega):\n",
" x_out = np.zeros_like(x_in)\n",
" # TODO -- write this function\n",
" # replace this line\n",
@@ -295,7 +306,7 @@
"cell_type": "code",
"source": [
"omega = [0.33,0.33,0.33]\n",
"h5 = conv_3_1_1_zp(x, omega)\n",
"h5 = conv_3_1_2_zp(x, omega)\n",
"\n",
"# Check that you have computed this correctly\n",
"print(f\"Sum of output is {np.sum(h5):3.3}, should be 68.3\")\n",
@@ -328,9 +339,9 @@
"cell_type": "code",
"source": [
"# Compute matrix in figure 10.4 d\n",
"def get_conv_mat_3_1_0_zp(n_out, omega):\n",
"def get_conv_mat_3_1_1_zp(n_out, omega):\n",
" omega_mat = np.zeros((n_out,n_out))\n",
" # TODO Fill in this matix\n",
" # TODO Fill in this matrix\n",
" # Replace this line:\n",
" omega_mat = omega_mat\n",
"\n",
@@ -349,11 +360,11 @@
"source": [
"# Run original convolution\n",
"omega = np.array([-1.0,0.5,-0.2])\n",
"h6 = conv_3_1_0_zp(x, omega)\n",
"h6 = conv_3_1_1_zp(x, omega)\n",
"print(h6)\n",
"\n",
"# If you have done this right, you should get the same answer\n",
"omega_mat = get_conv_mat_3_1_0_zp(len(x), omega)\n",
"omega_mat = get_conv_mat_3_1_1_zp(len(x), omega)\n",
"h7 = np.matmul(omega_mat, x)\n",
"print(h7)\n"
],
@@ -373,4 +384,4 @@
}
}
]
}
}

15
Notebooks/Chap10/10_2_Convolution_for_MNIST_1D.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOgDisWDe/zHpfTGCH8AZ3i",
"authorship_tag": "ABX9TyNJodaaCLMRWL9vTl8B/iLI",
"include_colab_link": true
},
"kernelspec": {
@@ -128,11 +128,11 @@
"\n",
"\n",
"# TODO Create a model with the following layers\n",
"# 1. Convolutional layer, (input=length 40 and 1 channel, kernel size 3x3, stride 2, padding=\"valid\", 15 output channels )\n",
"# 1. Convolutional layer, (input=length 40 and 1 channel, kernel size 3, stride 2, padding=\"valid\", 15 output channels )\n",
"# 2. ReLU\n",
"# 3. Convolutional layer, (input=length 19 and 15 channels, kernel size 3x3, stride 2, padding=\"valid\", 15 output channels )\n",
"# 3. Convolutional layer, (input=length 19 and 15 channels, kernel size 3, stride 2, padding=\"valid\", 15 output channels )\n",
"# 4. ReLU\n",
"# 5. Convolutional layer, (input=length 9 and 15 channels, kernel size 3x3, stride 2, padding=\"valid\", 15 output channels)\n",
"# 5. Convolutional layer, (input=length 9 and 15 channels, kernel size 3, stride 2, padding=\"valid\", 15 output channels)\n",
"# 6. ReLU\n",
"# 7. Flatten (converts 4x15) to length 60\n",
"# 8. Linear layer (input size = 60, output size = 10)\n",
@@ -141,6 +141,9 @@
"# https://pytorch.org/docs/stable/generated/torch.nn.Flatten.html\n",
"# https://pytorch.org/docs/1.13/generated/torch.nn.Linear.html?highlight=linear#torch.nn.Linear\n",
"\n",
"# NOTE THAT THE CONVOLUTIONAL LAYERS NEED TO TAKE THE NUMBER OF INPUT CHANNELS AS A PARAMETER\n",
"# AND NOT THE INPUT SIZE.\n",
"\n",
"# Replace the following function:\n",
"model = nn.Sequential(\n",
"nn.Flatten(),\n",
@@ -185,9 +188,9 @@
"scheduler = StepLR(optimizer, step_size=20, gamma=0.5)\n",
"# create 100 dummy data points and store in data loader class\n",
"x_train = torch.tensor(train_data_x.transpose().astype('float32'))\n",
"y_train = torch.tensor(train_data_y.astype('long'))\n",
"y_train = torch.tensor(train_data_y.astype('long')).long()\n",
"x_val= torch.tensor(val_data_x.transpose().astype('float32'))\n",
"y_val = torch.tensor(val_data_y.astype('long'))\n",
"y_val = torch.tensor(val_data_y.astype('long')).long()\n",
"\n",
"# load the data into a class that creates the batches\n",
"data_loader = DataLoader(TensorDataset(x_train,y_train), batch_size=100, shuffle=True, worker_init_fn=np.random.seed(1))\n",

7
Notebooks/Chap10/10_3_2D_Convolution.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyMmbD0cKYvIHXbKX4AupA1x",
"authorship_tag": "ABX9TyNDaU2KKZDyY9Ea7vm/fNxo",
"include_colab_link": true
},
"kernelspec": {
@@ -114,6 +114,11 @@
" # Create output\n",
" out = np.zeros((batchSize, channelsOut, imageHeightOut, imageWidthOut), dtype=np.float32)\n",
"\n",
" # !!!!!! NOTE THERE IS A SUBTLETY HERE !!!!!!!!\n",
" # I have padded the image with zeros above, so it is surrouned by a \"ring\" of zeros\n",
" # That means that the image indexes are all off by one\n",
" # This actually makes your code simpler\n",
"\n",
" for c_y in range(imageHeightOut):\n",
" for c_x in range(imageWidthOut):\n",
" for c_kernel_y in range(kernelHeight):\n",

10
Notebooks/Chap11/11_2_Residual_Networks.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyObut1y9atNUuowPT6dMY+I",
"authorship_tag": "ABX9TyMXS3SPB4cS/4qxix0lH/Hq",
"include_colab_link": true
},
"kernelspec": {
@@ -144,10 +144,10 @@
" def count_params(self):\n",
" return sum([p.view(-1).shape[0] for p in self.parameters()])\n",
"\n",
"# # TODO -- Add residual connections to this model\n",
"# # The order of operations should similar to figure 11.5b\n",
"# # linear1 first, ReLU+linear2 in first residual block, ReLU+linear3 in second residual block), linear4 at end\n",
"# # Replace this function\n",
"# TODO -- Add residual connections to this model\n",
"# The order of operations within each block should similar to figure 11.5b\n",
"# ie., linear1 first, ReLU+linear2 in first residual block, ReLU+linear3 in second residual block), linear4 at end\n",
"# Replace this function\n",
" def forward(self, x):\n",
" h1 = self.linear1(x).relu()\n",
" h2 = self.linear2(h1).relu()\n",

20
Notebooks/Chap11/11_3_Batch_Normalization.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOoGS+lY+EhGthebSO4smpj",
"authorship_tag": "ABX9TyPVeAd3eDpEOCFh8CVyr1zz",
"include_colab_link": true
},
"kernelspec": {
@@ -205,7 +205,8 @@
" self.linear3 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear4 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear5 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear6 = nn.Linear(hidden_size, output_size)\n",
" self.linear6 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear7 = nn.Linear(hidden_size, output_size)\n",
"\n",
" def count_params(self):\n",
" return sum([p.view(-1).shape[0] for p in self.parameters()])\n",
@@ -220,11 +221,11 @@
" print_variance(\"After second residual connection\",res2)\n",
" res3 = res2 + self.linear4(res2.relu())\n",
" print_variance(\"After third residual connection\",res3)\n",
" res4 = res3 + self.linear4(res3.relu())\n",
" res4 = res3 + self.linear5(res3.relu())\n",
" print_variance(\"After fourth residual connection\",res4)\n",
" res5 = res4 + self.linear4(res4.relu())\n",
" res5 = res4 + self.linear6(res4.relu())\n",
" print_variance(\"After fifth residual connection\",res5)\n",
" return self.linear6(res5)"
" return self.linear7(res5)"
],
"metadata": {
"id": "FslroPJJffrh"
@@ -272,7 +273,8 @@
" self.linear3 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear4 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear5 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear6 = nn.Linear(hidden_size, output_size)\n",
" self.linear6 = nn.Linear(hidden_size, hidden_size)\n",
" self.linear7 = nn.Linear(hidden_size, output_size)\n",
"\n",
" def count_params(self):\n",
" return sum([p.view(-1).shape[0] for p in self.parameters()])\n",
@@ -287,11 +289,11 @@
" print_variance(\"After second residual connection\",res2)\n",
" res3 = res2 + self.linear4(res2.relu())\n",
" print_variance(\"After third residual connection\",res3)\n",
" res4 = res3 + self.linear4(res3.relu())\n",
" res4 = res3 + self.linear5(res3.relu())\n",
" print_variance(\"After fourth residual connection\",res4)\n",
" res5 = res4 + self.linear4(res4.relu())\n",
" res5 = res4 + self.linear6(res4.relu())\n",
" print_variance(\"After fifth residual connection\",res5)\n",
" return self.linear6(res5)"
" return self.linear7(res5)"
],
"metadata": {
"id": "5JvMmaRITKGd"

6
Notebooks/Chap12/12_1_Self_Attention.ipynb
View File

@@ -31,7 +31,7 @@
"source": [
"# **Notebook 12.1: Self Attention**\n",
"\n",
"This notebook builds a self-attnetion mechanism from scratch, as discussed in section 12.2 of the book.\n",
"This notebook builds a self-attention mechanism from scratch, as discussed in section 12.2 of the book.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
@@ -153,7 +153,7 @@
{
"cell_type": "markdown",
"source": [
"We'll need a softmax function (equation 12.5) -- here, it will take a list of arbirtrary numbers and return a list where the elements are non-negative and sum to one\n"
"We'll need a softmax function (equation 12.5) -- here, it will take a list of arbitrary numbers and return a list where the elements are non-negative and sum to one\n"
],
"metadata": {
"id": "Se7DK6PGPSUk"
@@ -364,7 +364,7 @@
{
"cell_type": "markdown",
"source": [
"TODO -- Investigate whether the self-attention mechanism is covariant with respect to permulation.\n",
"TODO -- Investigate whether the self-attention mechanism is covariant with respect to permutation.\n",
"If it is, when we permute the columns of the input matrix $\\mathbf{X}$, the columns of the output matrix $\\mathbf{X}'$ will also be permuted.\n"
],
"metadata": {

2
Notebooks/Chap12/12_2_Multihead_Self_Attention.ipynb
View File

@@ -31,7 +31,7 @@
"source": [
"# **Notebook 12.1: Multhead Self-Attention**\n",
"\n",
"This notebook builds a multihead self-attentionm mechanism as in figure 12.6\n",
"This notebook builds a multihead self-attention mechanism as in figure 12.6\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",

4
Notebooks/Chap12/12_4_Decoding_Strategies.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyNPrHfkLWjy3NfDHRhGG3IE",
"authorship_tag": "ABX9TyPsZjfqVeHYh95Hzt+hCIO7",
"include_colab_link": true
},
"kernelspec": {
@@ -409,7 +409,7 @@
" print(\"Choosing from %d tokens\"%(thresh_index))\n",
" # TODO: Find the probability value to threshold\n",
" # Replace this line:\n",
" thresh_prob = sorted_probs_decreasing[thresh_index]\n",
" thresh_prob = 0.5\n",
"\n",
"\n",
"\n",

8
Notebooks/Chap13/13_2_Graph_Classification.ipynb
View File

@@ -57,7 +57,7 @@
{
"cell_type": "markdown",
"source": [
"Let's build a model that maps a chemical structure to a binary decision. This model might be used to predict whether a chemical is liquid at room temparature or not. We'll start by drawing the chemical structure."
"Let's build a model that maps a chemical structure to a binary decision. This model might be used to predict whether a chemical is liquid at room temperature or not. We'll start by drawing the chemical structure."
],
"metadata": {
"id": "UNleESc7k5uB"
@@ -191,7 +191,7 @@
"source": [
"# Let's test this network\n",
"f = graph_neural_network(A,X, Omega0, beta0, Omega1, beta1, Omega2, beta2, omega3, beta3)\n",
"print(\"Your value is %3f: \"%(f[0,0]), \"True value of f: 0.498010\")"
"print(\"Your value is %3f: \"%(f[0,0]), \"True value of f: 0.310843\")"
],
"metadata": {
"id": "X7gYgOu6uIAt"
@@ -221,7 +221,7 @@
"X_permuted = np.copy(X)\n",
"\n",
"f = graph_neural_network(A_permuted,X_permuted, Omega0, beta0, Omega1, beta1, Omega2, beta2, omega3, beta3)\n",
"print(\"Your value is %3f: \"%(f[0,0]), \"True value of f: 0.498010\")"
"print(\"Your value is %3f: \"%(f[0,0]), \"True value of f: 0.310843\")"
],
"metadata": {
"id": "F0zc3U_UuR5K"
@@ -241,4 +241,4 @@
}
}
]
}
}

4
Notebooks/Chap13/13_3_Neighborhood_Sampling.ipynb
View File

@@ -268,7 +268,7 @@
"source": [
"# TODO Find the nodes in hidden layer 1 that connect to the nodes in hidden layer 2\n",
"# using the adjacency matrix. Then sample n_sample of these nodes randomly without\n",
"# replacement. Make sure not to sample nodes that were already included in hidden layer 2 our the ouput layer.\n",
"# replacement. Make sure not to sample nodes that were already included in hidden layer 2 our the output layer.\n",
"# The nodes at hidden layer 1 are the union of these nodes and the nodes in hidden layer 2\n",
"\n",
"# Replace this line:\n",
@@ -311,4 +311,4 @@
}
}
]
}
}

6
Notebooks/Chap15/15_1_GAN_Toy_Example.ipynb
View File

@@ -31,7 +31,7 @@
"source": [
"# **Notebook 15.1: GAN Toy example**\n",
"\n",
"This notebook investigates the GAN toy example as illustred in figure 15.1 in the book.\n",
"This notebook investigates the GAN toy example as illustrated in figure 15.1 in the book.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
@@ -101,7 +101,7 @@
{
"cell_type": "markdown",
"source": [
"Now, we define our disriminator. This is a simple logistic regression model (1D linear model passed through sigmoid) that returns the probability that the data is real"
"Now, we define our discriminator. This is a simple logistic regression model (1D linear model passed through sigmoid) that returns the probability that the data is real"
],
"metadata": {
"id": "Xrzd8aehYAYR"
@@ -387,7 +387,7 @@
"print(\"Final parameters (phi0,phi1)\", phi0, phi1)\n",
"for c_gan_iter in range(5):\n",
"\n",
" # Run generator to product syntehsized data\n",
" # Run generator to product synthesized data\n",
" x_syn = generator(z, theta)\n",
" draw_data_model(x_real, x_syn, phi0, phi1)\n",
"\n",

4
Notebooks/Chap15/15_2_Wasserstein_Distance.ipynb
View File

@@ -29,9 +29,9 @@
{
"cell_type": "markdown",
"source": [
"# **Notebook 15.2: Wassserstein Distance**\n",
"# **Notebook 15.2: Wasserstein Distance**\n",
"\n",
"This notebook investigates the GAN toy example as illustred in figure 15.1 in the book.\n",
"This notebook investigates the GAN toy example as illustrated in figure 15.1 in the book.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",

6
Notebooks/Chap16/16_2_Autoregressive_Flows.ipynb
View File

@@ -65,7 +65,7 @@
{
"cell_type": "code",
"source": [
"# First let's make the 1D piecewise linear mapping as illustated in figure 16.5\n",
"# First let's make the 1D piecewise linear mapping as illustrated in figure 16.5\n",
"def g(h, phi):\n",
" # TODO -- write this function (equation 16.12)\n",
" # Note: If you have the first printing of the book, there is a mistake in equation 16.12\n",
@@ -156,7 +156,7 @@
{
"cell_type": "markdown",
"source": [
"Now let's define an autogressive flow. Let's switch to looking at figure 16.7.# We'll assume that our piecewise function will use five parameters phi1,phi2,phi3,phi4,phi5"
"Now let's define an autoregressive flow. Let's switch to looking at figure 16.7.# We'll assume that our piecewise function will use five parameters phi1,phi2,phi3,phi4,phi5"
],
"metadata": {
"id": "t8XPxipfd7hz"
@@ -175,7 +175,7 @@
" x = x/ np.sum(x) ;\n",
" return x\n",
"\n",
"# Return value of phi that doesn't depend on any of the iputs\n",
"# Return value of phi that doesn't depend on any of the inputs\n",
"def get_phi():\n",
" return np.array([0.2, 0.1, 0.4, 0.05, 0.25])\n",
"\n",

8
Notebooks/Chap17/17_1_Latent_Variable_Models.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyMBYNsjj1iTgHUYhAXqUYJd",
"authorship_tag": "ABX9TyOSEQVqxE5KrXmsZVh9M3gq",
"include_colab_link": true
},
"kernelspec": {
@@ -253,7 +253,7 @@
"pr_x1_x2_given_z_val = get_likelihood(x1_mesh,x2_mesh, z_val)\n",
"\n",
"# Plot the result\n",
"plot_heatmap(x1_mesh, x2_mesh, pr_x1_x2_given_z_val, title=\"Conditional distribution $Pr(x1,x2|z)$\")\n",
"plot_heatmap(x1_mesh, x2_mesh, pr_x1_x2_given_z_val, title=\"Conditional distribution $Pr(x_1,x_2|z)$\")\n",
"\n",
"# TODO -- Experiment with different values of z and make sure that you understand the what is happening."
],
@@ -292,7 +292,7 @@
"\n",
"\n",
"# Plot the result\n",
"plot_heatmap(x1_mesh, x2_mesh, pr_x1_x2, title=\"Data density $Pr(x1,x2)$\")\n"
"plot_heatmap(x1_mesh, x2_mesh, pr_x1_x2, title=\"Data density $Pr(x_1,x_2)$\")\n"
],
"metadata": {
"id": "H0Ijce9VzeCO"
@@ -341,7 +341,7 @@
"source": [
"x1_samples, x2_samples = draw_samples(500)\n",
"# Plot the result\n",
"plot_heatmap(x1_mesh, x2_mesh, pr_x1_x2, x1_samples, x2_samples, title=\"Data density $Pr(x1,x2)$\")\n"
"plot_heatmap(x1_mesh, x2_mesh, pr_x1_x2, x1_samples, x2_samples, title=\"Data density $Pr(x_1,x_2)$\")\n"
],
"metadata": {
"id": "XRmWv99B-BWO"

2
Notebooks/Chap17/17_2_Reparameterization_Trick.ipynb
View File

@@ -83,7 +83,7 @@
{
"cell_type": "code",
"source": [
"# Let's approximate this expecctation for a particular value of phi\n",
"# Let's approximate this expectation for a particular value of phi\n",
"def compute_expectation(phi, n_samples):\n",
" # TODO complete this function\n",
" # 1. Compute the mean of the normal distribution, mu\n",

4
Notebooks/Chap17/17_3_Importance_Sampling.ipynb
View File

@@ -4,7 +4,7 @@
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyMvae+1cigwg2Htl6vt1Who",
"authorship_tag": "ABX9TyNecz9/CDOggPSmy1LjT/Dv",
"include_colab_link": true
},
"kernelspec": {
@@ -217,7 +217,7 @@
" \\mbox{f}[y]= 20.446\\exp\\left[-(y-3)^4\\right],\n",
" \\end{equation}\n",
"\n",
"which decreases rapidly as we move away from the position $y=4$."
"which decreases rapidly as we move away from the position $y=3$."
],
"metadata": {
"id": "6hxsl3Pxo1TT"

296
Notebooks/Chap18/18_1_Diffusion_Encoder.ipynb
View File

@@ -1,26 +1,10 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyMpC8kgLnXx0XQBtwNAQ4jJ",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
"colab_type": "text",
"id": "view-in-github"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap18/18_1_Diffusion_Encoder.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
@@ -28,6 +12,9 @@
},
{
"cell_type": "markdown",
"metadata": {
"id": "t9vk9Elugvmi"
},
"source": [
"# **Notebook 18.1: Diffusion Encoder**\n",
"\n",
@@ -36,27 +23,29 @@
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions."
],
"metadata": {
"id": "t9vk9Elugvmi"
}
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "OLComQyvCIJ7"
},
"outputs": [],
"source": [
"import numpy as np\n",
"import matplotlib.pyplot as plt\n",
"from matplotlib.colors import ListedColormap\n",
"from operator import itemgetter"
],
"metadata": {
"id": "OLComQyvCIJ7"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "4PM8bf6lO0VE"
},
"outputs": [],
"source": [
"#Create pretty colormap as in book\n",
"my_colormap_vals_hex =('2a0902', '2b0a03', '2c0b04', '2d0c05', '2e0c06', '2f0d07', '300d08', '310e09', '320f0a', '330f0b', '34100b', '35110c', '36110d', '37120e', '38120f', '39130f', '3a1410', '3b1411', '3c1511', '3d1612', '3e1613', '3f1713', '401714', '411814', '421915', '431915', '451a16', '461b16', '471b17', '481c17', '491d18', '4a1d18', '4b1e19', '4c1f19', '4d1f1a', '4e201b', '50211b', '51211c', '52221c', '53231d', '54231d', '55241e', '56251e', '57261f', '58261f', '592720', '5b2821', '5c2821', '5d2922', '5e2a22', '5f2b23', '602b23', '612c24', '622d25', '632e25', '652e26', '662f26', '673027', '683027', '693128', '6a3229', '6b3329', '6c342a', '6d342a', '6f352b', '70362c', '71372c', '72372d', '73382e', '74392e', '753a2f', '763a2f', '773b30', '783c31', '7a3d31', '7b3e32', '7c3e33', '7d3f33', '7e4034', '7f4134', '804235', '814236', '824336', '834437', '854538', '864638', '874739', '88473a', '89483a', '8a493b', '8b4a3c', '8c4b3c', '8d4c3d', '8e4c3e', '8f4d3f', '904e3f', '924f40', '935041', '945141', '955242', '965343', '975343', '985444', '995545', '9a5646', '9b5746', '9c5847', '9d5948', '9e5a49', '9f5a49', 'a05b4a', 'a15c4b', 'a35d4b', 'a45e4c', 'a55f4d', 'a6604e', 'a7614e', 'a8624f', 'a96350', 'aa6451', 'ab6552', 'ac6552', 'ad6653', 'ae6754', 'af6855', 'b06955', 'b16a56', 'b26b57', 'b36c58', 'b46d59', 'b56e59', 'b66f5a', 'b7705b', 'b8715c', 'b9725d', 'ba735d', 'bb745e', 'bc755f', 'bd7660', 'be7761', 'bf7862', 'c07962', 'c17a63', 'c27b64', 'c27c65', 'c37d66', 'c47e67', 'c57f68', 'c68068', 'c78169', 'c8826a', 'c9836b', 'ca846c', 'cb856d', 'cc866e', 'cd876f', 'ce886f', 'ce8970', 'cf8a71', 'd08b72', 'd18c73', 'd28d74', 'd38e75', 'd48f76', 'd59077', 'd59178', 'd69279', 'd7937a', 'd8957b', 'd9967b', 'da977c', 'da987d', 'db997e', 'dc9a7f', 'dd9b80', 'de9c81', 'de9d82', 'df9e83', 'e09f84', 'e1a185', 'e2a286', 'e2a387', 'e3a488', 'e4a589', 'e5a68a', 'e5a78b', 'e6a88c', 'e7aa8d', 'e7ab8e', 'e8ac8f', 'e9ad90', 'eaae91', 'eaaf92', 'ebb093', 'ecb295', 'ecb396', 'edb497', 'eeb598', 'eeb699', 'efb79a', 'efb99b', 'f0ba9c', 'f1bb9d', 'f1bc9e', 'f2bd9f', 'f2bfa1', 'f3c0a2', 'f3c1a3', 'f4c2a4', 'f5c3a5', 'f5c5a6', 'f6c6a7', 'f6c7a8', 'f7c8aa', 'f7c9ab', 'f8cbac', 'f8ccad', 'f8cdae', 'f9ceb0', 'f9d0b1', 'fad1b2', 'fad2b3', 'fbd3b4', 'fbd5b6', 'fbd6b7', 'fcd7b8', 'fcd8b9', 'fcdaba', 'fddbbc', 'fddcbd', 'fddebe', 'fddfbf', 'fee0c1', 'fee1c2', 'fee3c3', 'fee4c5', 'ffe5c6', 'ffe7c7', 'ffe8c9', 'ffe9ca', 'ffebcb', 'ffeccd', 'ffedce', 'ffefcf', 'fff0d1', 'fff2d2', 'fff3d3', 'fff4d5', 'fff6d6', 'fff7d8', 'fff8d9', 'fffada', 'fffbdc', 'fffcdd', 'fffedf', 'ffffe0')\n",
@@ -66,28 +55,28 @@
"b = np.floor(my_colormap_vals_dec - r * 256 *256 - g * 256)\n",
"my_colormap_vals = np.vstack((r,g,b)).transpose()/255.0\n",
"my_colormap = ListedColormap(my_colormap_vals)"
],
"metadata": {
"id": "4PM8bf6lO0VE"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "ONGRaQscfIOo"
},
"outputs": [],
"source": [
"# Probability distribution for normal\n",
"def norm_pdf(x, mu, sigma):\n",
" return np.exp(-0.5 * (x-mu) * (x-mu) / (sigma * sigma)) / np.sqrt(2*np.pi*sigma*sigma)"
],
"metadata": {
"id": "ONGRaQscfIOo"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "gZvG0MKhfY8Y"
},
"outputs": [],
"source": [
"# True distribution is a mixture of four Gaussians\n",
"class TrueDataDistribution:\n",
@@ -108,15 +97,15 @@
" mu_list = list(itemgetter(*hidden)(self.mu))\n",
" sigma_list = list(itemgetter(*hidden)(self.sigma))\n",
" return mu_list + sigma_list * epsilon"
],
"metadata": {
"id": "gZvG0MKhfY8Y"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "qXmej3TUuQyp"
},
"outputs": [],
"source": [
"# Define ground truth probability distribution that we will model\n",
"true_dist = TrueDataDistribution()\n",
@@ -130,24 +119,24 @@
"ax.set_ylim(0,1.0)\n",
"ax.set_xlim(-3,3)\n",
"plt.show()"
],
"metadata": {
"id": "qXmej3TUuQyp"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "markdown",
"source": [
"Let's first implement the forward process"
],
"metadata": {
"id": "XHdtfRP47YLy"
}
},
"source": [
"Let's first implement the forward process"
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "hkApJ2VJlQuk"
},
"outputs": [],
"source": [
"# Do one step of diffusion (equation 18.1)\n",
"def diffuse_one_step(z_t_minus_1, beta_t):\n",
@@ -157,24 +146,24 @@
" z_t = np.zeros_like(z_t_minus_1)\n",
"\n",
" return z_t"
],
"metadata": {
"id": "hkApJ2VJlQuk"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "markdown",
"source": [
"Now let's run the diffusion process for a whole bunch of samples"
],
"metadata": {
"id": "ECAUfHNi9NVW"
}
},
"source": [
"Now let's run the diffusion process for a whole bunch of samples"
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "M-TY5w9Q8LYW"
},
"outputs": [],
"source": [
"# Generate some samples\n",
"n_sample = 10000\n",
@@ -192,24 +181,24 @@
"\n",
"for t in range(T):\n",
" samples[t+1,:] = diffuse_one_step(samples[t,:], beta)"
],
"metadata": {
"id": "M-TY5w9Q8LYW"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "markdown",
"source": [
"Let's, plot the evolution of a few paths as in figure 18.2"
],
"metadata": {
"id": "jYrAW6tN-gJ4"
}
},
"source": [
"Let's, plot the evolution of a few paths as in figure 18.2"
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "4XU6CDZC_kFo"
},
"outputs": [],
"source": [
"fig, ax = plt.subplots()\n",
"t_vals = np.arange(0,101,1)\n",
@@ -223,24 +212,24 @@
"ax.set_xlabel('value')\n",
"ax.set_ylabel('z_{t}')\n",
"plt.show()"
],
"metadata": {
"id": "4XU6CDZC_kFo"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "markdown",
"source": [
"Notice that the samples have a tendencey to move toward the center. Now let's look at the histogram of the samples at each stage"
],
"metadata": {
"id": "SGTYGGevAktz"
}
},
"source": [
"Notice that the samples have a tendency to move toward the center. Now let's look at the histogram of the samples at each stage"
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "bn5E5NzL-evM"
},
"outputs": [],
"source": [
"def draw_hist(z_t,title=''):\n",
" fig, ax = plt.subplots()\n",
@@ -248,17 +237,17 @@
" plt.hist(z_t , bins=np.arange(-3,3, 0.1), density = True)\n",
" ax.set_xlim([-3,3])\n",
" ax.set_ylim([0,1.0])\n",
" ax.set_title('title')\n",
" ax.set_title(title)\n",
" plt.show()"
],
"metadata": {
"id": "bn5E5NzL-evM"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "pn_XD-EhBlwk"
},
"outputs": [],
"source": [
"draw_hist(samples[0,:],'Original data')\n",
"draw_hist(samples[5,:],'Time step 5')\n",
@@ -267,33 +256,33 @@
"draw_hist(samples[40,:],'Time step 40')\n",
"draw_hist(samples[80,:],'Time step 80')\n",
"draw_hist(samples[100,:],'Time step 100')"
],
"metadata": {
"id": "pn_XD-EhBlwk"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "markdown",
"source": [
"You can clearly see that as the diffusion process continues, the data becomes more Gaussian."
],
"metadata": {
"id": "skuLfGl5Czf4"
}
},
"source": [
"You can clearly see that as the diffusion process continues, the data becomes more Gaussian."
]
},
{
"cell_type": "markdown",
"source": [
"Now let's investigate the diffusion kernel as in figure 18.3 of the book.\n"
],
"metadata": {
"id": "s37CBSzzK7wh"
}
},
"source": [
"Now let's investigate the diffusion kernel as in figure 18.3 of the book.\n"
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "vL62Iym0LEtY"
},
"outputs": [],
"source": [
"def diffusion_kernel(x, t, beta):\n",
" # TODO -- write this function\n",
@@ -301,15 +290,15 @@
" dk_mean = 0.0 ; dk_std = 1.0\n",
"\n",
" return dk_mean, dk_std"
],
"metadata": {
"id": "vL62Iym0LEtY"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "KtP1KF8wMh8o"
},
"outputs": [],
"source": [
"def draw_prob_dist(x_plot_vals, prob_dist, title=''):\n",
" fig, ax = plt.subplots()\n",
@@ -363,47 +352,47 @@
" draw_prob_dist(x_plot_vals, diffusion_kernels[20,:],'$q(z_{20}|x)$')\n",
" draw_prob_dist(x_plot_vals, diffusion_kernels[40,:],'$q(z_{40}|x)$')\n",
" draw_prob_dist(x_plot_vals, diffusion_kernels[80,:],'$q(z_{80}|x)$')"
],
"metadata": {
"id": "KtP1KF8wMh8o"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"source": [
"x = -2\n",
"compute_and_plot_diffusion_kernels(x, T, beta, my_colormap)"
],
"execution_count": null,
"metadata": {
"id": "g8TcI5wtRQsx"
},
"execution_count": null,
"outputs": []
"outputs": [],
"source": [
"x = -2\n",
"compute_and_plot_diffusion_kernels(x, T, beta, my_colormap)"
]
},
{
"cell_type": "markdown",
"source": [
"TODO -- Run this for different version of $x$ and check that you understand how the graphs change"
],
"metadata": {
"id": "-RuN2lR28-hK"
}
},
"source": [
"TODO -- Run this for different version of $x$ and check that you understand how the graphs change"
]
},
{
"cell_type": "markdown",
"metadata": {
"id": "n-x6Whz2J_zy"
},
"source": [
"Finally, let's estimate the marginal distributions empirically and visualize them as in figure 18.4 of the book. This is only tractable because the data is in one dimension and we know the original distribution.\n",
"\n",
"The marginal distribution at time t is the sum of the diffusion kernels for each position x, weighted by the probability of seeing that value of x in the true distribution."
],
"metadata": {
"id": "n-x6Whz2J_zy"
}
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "YzN5duYpg7C-"
},
"outputs": [],
"source": [
"def diffusion_marginal(x_plot_vals, pr_x_true, t, beta):\n",
" # If time is zero then marginal is just original distribution\n",
@@ -414,7 +403,7 @@
" marginal_at_time_t = np.zeros_like(pr_x_true);\n",
"\n",
"\n",
" # TODO Write ths function\n",
" # TODO Write this function\n",
" # 1. For each x (value in x_plot_vals):\n",
" # 2. Compute the mean and variance of the diffusion kernel at time t\n",
" # 3. Compute pdf of this Gaussian at every x_plot_val\n",
@@ -427,15 +416,15 @@
"\n",
"\n",
" return marginal_at_time_t"
],
"metadata": {
"id": "YzN5duYpg7C-"
},
"execution_count": null,
"outputs": []
]
},
{
"cell_type": "code",
"execution_count": null,
"metadata": {
"id": "OgEU9sxjRaeO"
},
"outputs": [],
"source": [
"x_plot_vals = np.arange(-3,3,0.01)\n",
"marginal_distributions = np.zeros((T+1,len(x_plot_vals)))\n",
@@ -460,12 +449,23 @@
"draw_prob_dist(x_plot_vals, marginal_distributions[0,:],'$q(z_{0})$')\n",
"draw_prob_dist(x_plot_vals, marginal_distributions[20,:],'$q(z_{20})$')\n",
"draw_prob_dist(x_plot_vals, marginal_distributions[60,:],'$q(z_{60})$')"
],
"metadata": {
"id": "OgEU9sxjRaeO"
},
"execution_count": null,
"outputs": []
]
}
]
}
],
"metadata": {
"colab": {
"authorship_tag": "ABX9TyMpC8kgLnXx0XQBtwNAQ4jJ",
"include_colab_link": true,
"provenance": []
},
"kernelspec": {
"display_name": "Python 3",
"name": "python3"
},
"language_info": {
"name": "python"
}
},
"nbformat": 4,
"nbformat_minor": 0
}

2
Notebooks/Chap18/18_2_1D_Diffusion_Model.ipynb
View File

@@ -172,7 +172,7 @@
" # Find diffusion kernel for every x_train and draw samples\n",
" dk_mean, dk_std = diffusion_kernel(x_train, t, beta)\n",
" z_t = np.random.normal(size=x_train.shape) * dk_std + dk_mean\n",
" # Find conditional diffusion distribution for each x_train, z pair and draw samlpes\n",
" # Find conditional diffusion distribution for each x_train, z pair and draw samples\n",
" cd_mean, cd_std = conditional_diffusion_distribution(x_train,z_t,t,beta)\n",
" if t == 1:\n",
" z_tminus1 = x_train\n",

6
Notebooks/Chap19/19_1_Markov_Decision_Processes.ipynb
View File

@@ -598,7 +598,7 @@
"source": [
"def markov_decision_process_step_deterministic(state, transition_probabilities_given_action, reward_structure, policy):\n",
" # TODO -- complete this function.\n",
" # For each state, theres is a corresponding action.\n",
" # For each state, there's is a corresponding action.\n",
" # Draw the next state based on the current state and that action\n",
" # and calculate the reward\n",
" # Replace this line:\n",
@@ -683,7 +683,7 @@
"source": [
"def markov_decision_process_step_stochastic(state, transition_probabilities_given_action, reward_structure, stochastic_policy):\n",
" # TODO -- complete this function.\n",
" # For each state, theres is a corresponding distribution over actions\n",
" # For each state, there's is a corresponding distribution over actions\n",
" # Draw a sample from that distribution to get the action\n",
" # Draw the next state based on the current state and that action\n",
" # and calculate the reward\n",
@@ -733,4 +733,4 @@
"outputs": []
}
]
}
}

271
Notebooks/Chap19/19_2_Dynamic_Programming.ipynb
View File

File diff suppressed because one or more lines are too long

2
Notebooks/Chap19/19_4_Temporal_Difference_Methods.ipynb
View File

@@ -31,7 +31,7 @@
"source": [
"# **Notebook 19.4: Temporal difference methods**\n",
"\n",
"This notebook investigates temporal differnece methods for tabular reinforcement learning as described in section 19.3.3 of the book\n",
"This notebook investigates temporal difference methods for tabular reinforcement learning as described in section 19.3.3 of the book\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",

2
Notebooks/Chap19/19_5_Control_Variates.ipynb
View File

@@ -57,7 +57,7 @@
{
"cell_type": "markdown",
"source": [
"Genearate from our two variables, $a$ and $b$. We are interested in estimating the mean of $a$, but we can use $b$$ to improve our estimates if it is correlated"
"Generate from our two variables, $a$ and $b$. We are interested in estimating the mean of $a$, but we can use $b$$ to improve our estimates if it is correlated"
],
"metadata": {
"id": "uwmhcAZBzTRO"

296
Notebooks/Chap20/20_2_Full_Batch_Gradient_Descent.ipynb Normal file
View File

@@ -0,0 +1,296 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOo4vm4MXcIvAzVlMCaLikH",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap20/20_2_Full_Batch_Gradient_Descent.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# **Notebook 20.2: Full Batch Gradient Descent**\n",
"\n",
"This notebook investigates training a network with full batch gradient descent as in figure 20.2. There is also a version (notebook takes a long time to run), but this didn't speed it up much for me. If you run out of CoLab time, you'll need to download the Python file and run locally.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions."
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"# Run this if you're in a Colab to make a local copy of the MNIST 1D repository\n",
"!git clone https://github.com/greydanus/mnist1d"
],
"metadata": {
"id": "D5yLObtZCi9J"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import os\n",
"import torch, torch.nn as nn\n",
"from torch.utils.data import TensorDataset, DataLoader\n",
"from torch.optim.lr_scheduler import StepLR\n",
"import matplotlib.pyplot as plt\n",
"import mnist1d\n",
"import random\n",
"from IPython.display import display, clear_output"
],
"metadata": {
"id": "YrXWAH7sUWvU"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"args = mnist1d.data.get_dataset_args()\n",
"data = mnist1d.data.get_dataset(args, path='./mnist1d_data.pkl', download=False, regenerate=False)\n",
"\n",
"# The training and test input and outputs are in\n",
"# data['x'], data['y']\n",
"print(\"Examples in training set: {}\".format(len(data['y'])))\n",
"print(\"Length of each example: {}\".format(data['x'].shape[-1]))"
],
"metadata": {
"id": "twI72ZCrCt5z"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Define the network"
],
"metadata": {
"id": "_sFvRDGrl4qe"
}
},
{
"cell_type": "code",
"source": [
"# Data is length forty, and there are 10 classes\n",
"D_i = 40\n",
"D_o = 10\n",
"\n",
"# create model with one hidden layer and 298 hidden units\n",
"model_1_layer = nn.Sequential(\n",
"nn.Linear(D_i, 298),\n",
"nn.ReLU(),\n",
"nn.Linear(298, D_o))\n",
"\n",
"\n",
"# TODO -- create model with three hidden layers and 100 hidden units per layer\n",
"# Replace this line\n",
"model_2_layer = nn.Sequential(nn.Linear(D_i, D_o))\n",
"\n",
"\n",
"\n",
"# TODO -- Create model with three hidden layers and 75 hidden units per layer\n",
"# Replace this line\n",
"model_3_layer = nn.Sequential(nn.Linear(D_i, D_o))\n",
"\n",
"\n",
"\n",
"# TODO create model with four hidden layers and 63 hidden units per layer\n",
"# Replace this line\n",
"model_4_layer = nn.Sequential(nn.Linear(D_i, D_o))\n",
"\n"
],
"metadata": {
"id": "FslroPJJffrh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# He initialization of weights\n",
"def weights_init(layer_in):\n",
" if isinstance(layer_in, nn.Linear):\n",
" nn.init.kaiming_uniform_(layer_in.weight)\n",
" layer_in.bias.data.fill_(0.0)"
],
"metadata": {
"id": "YgLaex1pfhqz"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"def train_model(model, train_data_x, train_data_y, n_epoch):\n",
" print(\"This is going to take a long time!\")\n",
" # choose cross entropy loss function (equation 5.24 in the loss notes)\n",
" loss_function = nn.CrossEntropyLoss()\n",
" # construct SGD optimizer and initialize learning rate to small value and momentum to 0\n",
" optimizer = torch.optim.SGD(model.parameters(), lr = 0.0025, momentum=0.0)\n",
" # create 100 dummy data points and store in data loader class\n",
" x_train = torch.tensor(train_data_x.transpose().astype('float32'))\n",
" y_train = torch.tensor(train_data_y.astype('long'))\n",
"\n",
" # load the data into a class that creates the batches -- full batch as there are 4000 examples\n",
" data_loader = DataLoader(TensorDataset(x_train,y_train), batch_size=4000, shuffle=False, worker_init_fn=np.random.seed(1))\n",
"\n",
" # Initialize model weights\n",
" model.apply(weights_init)\n",
"\n",
" # store the errors percentage at each point\n",
" errors_train = np.zeros((n_epoch))\n",
"\n",
" for epoch in range(n_epoch):\n",
" # loop over batches\n",
" for i, data in enumerate(data_loader):\n",
" # retrieve inputs and labels for this batch\n",
" x_batch, y_batch = data\n",
" # zero the parameter gradients\n",
" optimizer.zero_grad()\n",
" # forward pass -- calculate model output\n",
" pred = model(x_batch)\n",
" # compute the loss\n",
" loss = loss_function(pred, y_batch)\n",
" # Store the errors\n",
" _, predicted_train_class = torch.max(pred.data, 1)\n",
" errors_train[epoch] = 100 - 100 * (predicted_train_class == y_train).float().sum() / len(y_train)\n",
" # backward pass\n",
" loss.backward()\n",
" # SGD update\n",
" optimizer.step()\n",
"\n",
" if epoch % 10 == 0:\n",
" clear_output(wait=True)\n",
" display(\"Epoch %d, errors_train %3.3f\"%(epoch, errors_train[epoch]))\n",
"\n",
" return errors_train"
],
"metadata": {
"id": "NYw8I_3mmX5c"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Load in the data\n",
"train_data_x = data['x'].transpose()\n",
"train_data_y = data['y']\n",
"# Print out sizes\n",
"print(\"Train data: %d examples (columns), each of which has %d dimensions (rows)\"%((train_data_x.shape[1],train_data_x.shape[0])))"
],
"metadata": {
"id": "4FE3HQ_vedXO"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Train the models\n",
"errors_four_layers = train_model(model_4_layer, train_data_x, train_data_y, n_epoch=200000)"
],
"metadata": {
"id": "b56wdODqemF1"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"errors_three_layers = train_model(model_3_layer, train_data_x, train_data_y, n_epoch=200000)\n"
],
"metadata": {
"id": "hqY-MJVPnCBV"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"errors_two_layers = train_model(model_2_layer, train_data_x, train_data_y, n_epoch=200000)\n"
],
"metadata": {
"id": "T61jfpNGnDGj"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"errors_one_layer = train_model(model_1_layer, train_data_x, train_data_y, n_epoch=500000)"
],
"metadata": {
"id": "HO8ZFgYqnEQe"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Plot the results\n",
"fig, ax = plt.subplots()\n",
"ax.plot(errors_one_layer,'r-',label='one layer')\n",
"ax.plot(errors_two_layers,'g-',label='two layers')\n",
"ax.plot(errors_three_layers,'b-',label='three layers')\n",
"ax.plot(errors_four_layers,'m-',label='four layers')\n",
"ax.set_ylim(0,100)\n",
"ax.set_xlabel('Epoch'); ax.set_ylabel('Percent error')\n",
"ax.legend()\n",
"plt.show()"
],
"metadata": {
"id": "pYL0YMI5oNSR"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [],
"metadata": {
"id": "wJerga3M7eDw"
},
"execution_count": null,
"outputs": []
}
]
}

303
Notebooks/Chap20/20_2_Full_Batch_Gradient_Descent_GPU.ipynb Normal file
View File

@@ -0,0 +1,303 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"gpuType": "T4",
"authorship_tag": "ABX9TyMjPBfDONmjqTSyEQDP2gjY",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
},
"accelerator": "GPU"
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap20/20_2_Full_Batch_Gradient_Descent_GPU.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# **Notebook 20.2: Full Batch Gradient Descent**\n",
"\n",
"This notebook investigates training a network with full batch gradient descent as in figure 20.2. This is the GPU version (notebook takes a long time to run). If you are using Colab then you need to go change the runtime type to GPU on the Runtime menu. Even then, you may run out of time. If that's the case, you'll need to download the Python file and run locally.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions.\n",
"\n"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"# Run this if you're in a Colab to make a local copy of the MNIST 1D repository\n",
"!git clone https://github.com/greydanus/mnist1d"
],
"metadata": {
"id": "D5yLObtZCi9J"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import os\n",
"import torch, torch.nn as nn\n",
"from torch.utils.data import TensorDataset, DataLoader\n",
"from torch.optim.lr_scheduler import StepLR\n",
"import matplotlib.pyplot as plt\n",
"import mnist1d\n",
"import random\n",
"from IPython.display import display, clear_output\n",
"\n",
"\n",
"# Try attaching to GPU\n",
"DEVICE = str(torch.device('cuda' if torch.cuda.is_available() else 'cpu'))\n",
"print('Using:', DEVICE)"
],
"metadata": {
"id": "YrXWAH7sUWvU"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"args = mnist1d.data.get_dataset_args()\n",
"data = mnist1d.data.get_dataset(args, path='./mnist1d_data.pkl', download=False, regenerate=False)\n",
"\n",
"# The training and test input and outputs are in\n",
"# data['x'], data['y']\n",
"print(\"Examples in training set: {}\".format(len(data['y'])))\n",
"print(\"Length of each example: {}\".format(data['x'].shape[-1]))"
],
"metadata": {
"id": "twI72ZCrCt5z"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Define the network"
],
"metadata": {
"id": "_sFvRDGrl4qe"
}
},
{
"cell_type": "code",
"source": [
"# Data is length forty, and there are 10 classes\n",
"D_i = 40\n",
"D_o = 10\n",
"\n",
"# create model with one hidden layer and 298 hidden units\n",
"model_1_layer = nn.Sequential(\n",
"nn.Linear(D_i, 298),\n",
"nn.ReLU(),\n",
"nn.Linear(298, D_o))\n",
"\n",
"\n",
"# TODO -- create model with three hidden layers and 100 hidden units per layer\n",
"# Replace this line\n",
"model_2_layer = nn.Sequential(nn.Linear(D_i, D_o))\n",
"\n",
"# TODO -- Create model with three hidden layers and 75 hidden units per layer\n",
"# Replace this line\n",
"model_3_layer = nn.Sequential(nn.Linear(D_i, D_o))\n",
"\n",
"# TODO create model with four hidden layers and 63 hidden units per layer\n",
"# Replace this line\n",
"model_4_layer = nn.Sequential(nn.Linear(D_i, D_o))\n"
],
"metadata": {
"id": "FslroPJJffrh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# He initialization of weights\n",
"def weights_init(layer_in):\n",
" if isinstance(layer_in, nn.Linear):\n",
" nn.init.kaiming_uniform_(layer_in.weight)\n",
" layer_in.bias.data.fill_(0.0)"
],
"metadata": {
"id": "YgLaex1pfhqz"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"def train_model(model, train_data_x, train_data_y, n_epoch, DEVICE):\n",
" print(\"This is going to take a long time!\")\n",
" # choose cross entropy loss function (equation 5.24 in the loss notes)\n",
" loss_function = nn.CrossEntropyLoss()\n",
" # construct SGD optimizer and initialize learning rate to small value and momentum to 0\n",
" optimizer = torch.optim.SGD(model.parameters(), lr = 0.0025, momentum=0.0)\n",
" # create 100 dummy data points and store in data loader class\n",
" x_train = torch.tensor(train_data_x.transpose(), dtype=torch.float32, device=DEVICE)\n",
" y_train = torch.tensor(train_data_y, dtype=torch.long, device=DEVICE)\n",
"\n",
" # load the data into a class that creates the batches -- full batch as there are 4000 examples\n",
" data_loader = DataLoader(TensorDataset(x_train,y_train), batch_size=4000, shuffle=False, worker_init_fn=np.random.seed(1))\n",
"\n",
" # Initialize model weights\n",
" model.apply(weights_init)\n",
"\n",
" # store the errors percentage at each point\n",
" errors_train = np.zeros((n_epoch))\n",
"\n",
" for epoch in range(n_epoch):\n",
" # loop over batches\n",
" for i, data in enumerate(data_loader):\n",
" # retrieve inputs and labels for this batch\n",
" x_batch, y_batch = data\n",
" # zero the parameter gradients\n",
" optimizer.zero_grad()\n",
" # forward pass -- calculate model output\n",
" pred = model(x_batch)\n",
" # compute the loss\n",
" loss = loss_function(pred, y_batch)\n",
" # Store the errors\n",
" _, predicted_train_class = torch.max(pred.data, 1)\n",
" errors_train[epoch] = 100 - 100 * (predicted_train_class == y_train).float().sum() / len(y_train)\n",
" # backward pass\n",
" loss.backward()\n",
" # SGD update\n",
" optimizer.step()\n",
"\n",
" if epoch % 10 == 0:\n",
" clear_output(wait=True)\n",
" display(\"Epoch %d, errors_train %3.3f\"%(epoch, errors_train[epoch]))\n",
"\n",
" return errors_train"
],
"metadata": {
"id": "NYw8I_3mmX5c"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Load in the data\n",
"train_data_x = data['x'].transpose()\n",
"train_data_y = data['y']\n",
"# Print out sizes\n",
"print(\"Train data: %d examples (columns), each of which has %d dimensions (rows)\"%((train_data_x.shape[1],train_data_x.shape[0])))"
],
"metadata": {
"id": "4FE3HQ_vedXO"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Train the four models\n",
"model_4_layer = model_4_layer.to(DEVICE)\n",
"errors_four_layers = train_model(model_4_layer, train_data_x, train_data_y, n_epoch=200000, DEVICE=DEVICE)\n"
],
"metadata": {
"id": "b56wdODqemF1"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"model_3_layer = model_3_layer.to(DEVICE)\n",
"errors_three_layers = train_model(model_3_layer, train_data_x, train_data_y, n_epoch=200000, DEVICE=DEVICE)\n"
],
"metadata": {
"id": "63WsEgDCmbB4"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"model_2_layer = model_2_layer.to(DEVICE)\n",
"errors_two_layers = train_model(model_2_layer, train_data_x, train_data_y, n_epoch=200000, DEVICE=DEVICE)\n"
],
"metadata": {
"id": "3TfS5DaZmdCN"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"model_1_layer = model_1_layer.to(DEVICE)\n",
"errors_one_layer = train_model(model_1_layer, train_data_x, train_data_y, n_epoch=500000, DEVICE=DEVICE)"
],
"metadata": {
"id": "3f9Z6Mh4meeA"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Plot the results\n",
"fig, ax = plt.subplots()\n",
"ax.plot(errors_one_layer,'r-',label='one layer')\n",
"ax.plot(errors_two_layers,'g-',label='two layers')\n",
"ax.plot(errors_three_layers,'b-',label='three layers')\n",
"ax.plot(errors_four_layers,'m-',label='four layers')\n",
"ax.set_ylim(0,100)\n",
"ax.set_xlabel('Epoch'); ax.set_ylabel('Percent error')\n",
"ax.legend()\n",
"plt.show()"
],
"metadata": {
"id": "pYL0YMI5oNSR"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [],
"metadata": {
"id": "iJem05Y03mZB"
},
"execution_count": null,
"outputs": []
}
]
}

377
Notebooks/Chap20/20_3_Lottery_Tickets.ipynb Normal file
View File

@@ -0,0 +1,377 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap20/20_3_Lottery_Tickets.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"metadata": {
"id": "dKUcDM76bHx3"
},
"source": [
"# **Notebook 20.3: Lottery tickets**\n",
"\n",
"This notebook investigates the phenomenon of lottery tickets as discussed in section 20.2.7. This notebook is highly derivative of the MNIST-1D code hosted by Sam Greydanus at https://github.com/greydanus/mnist1d. \n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions."
]
},
{
"cell_type": "code",
"metadata": {
"id": "Sg2i1QmhKW5d"
},
"source": [
"# Run this if you're in a Colab\n",
"!git clone https://github.com/greydanus/mnist1d"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Lottery tickets\n",
"\n",
"Lottery tickets were first identified by [Frankle and Carbin (2018)](https://arxiv.org/abs/1803.03635). They noted that after training a network, they could set the smaller weights to zero and clamp them there and retrain to get a network that was sparser (had fewer parameters) but could actually perform better. So within the neural network there lie smaller sub-networks which are superior. If we knew what these were, we could train them from scratch, but there is currently no way of finding out."
],
"metadata": {
"id": "97g8gY5XdcKR"
}
},
{
"cell_type": "code",
"metadata": {
"id": "KaQo7QhvXvid"
},
"source": [
"import numpy as np\n",
"import matplotlib.pyplot as plt\n",
"\n",
"import torch\n",
"import torch.nn as nn\n",
"import torch.nn.functional as F\n",
"import torch.optim as optim\n",
"\n",
"import mnist1d\n",
"import copy"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"metadata": {
"id": "nre26wEOfZsM"
},
"source": [
"## Get the MNIST1D dataset"
]
},
{
"cell_type": "code",
"metadata": {
"id": "I-vm_gh5xTJs"
},
"source": [
"args = mnist1d.get_dataset_args()\n",
"data = mnist1d.get_dataset(args=args) # by default, this will download a pre-made dataset from the GitHub repo\n",
"\n",
"print(\"Examples in training set: {}\".format(len(data['y'])))\n",
"print(\"Examples in test set: {}\".format(len(data['y_test'])))\n",
"print(\"Length of each input: {}\".format(data['x'].shape[-1]))\n",
"print(\"Number of classes: {}\".format(len(data['templates']['y'])))"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"metadata": {
"id": "O2vy0FKjfDwr"
},
"source": [
"## Make an MLP that can be masked\n",
"These parameter-wise binary masks are how we will represent sparsity in this project. There's not a great PyTorch API for this yet, so here's a temporary solution."
]
},
{
"cell_type": "code",
"metadata": {
"id": "uBx5gNW-mqH_"
},
"source": [
"# Class to represent linear layer where some of the weights are forced to zero.\n",
"class SparseLinear(torch.nn.Module):\n",
" def __init__(self, x_size, y_size):\n",
" super(SparseLinear, self).__init__()\n",
" self.linear = torch.nn.Linear(x_size, y_size)\n",
" param_vec = torch.cat([p.flatten() for p in self.parameters()])\n",
" self.mask = torch.ones_like(param_vec)\n",
"\n",
" def forward(self, x, apply_mask=True):\n",
" if apply_mask:\n",
" self.apply_mask()\n",
" return self.linear(x)\n",
"\n",
" def update_mask(self, new_mask):\n",
" self.mask = new_mask\n",
" self.apply_mask()\n",
"\n",
" def apply_mask(self):\n",
" self.vec2param(self.param2vec())\n",
"\n",
" def param2vec(self):\n",
" vec = torch.cat([p.flatten() for p in self.parameters()])\n",
" return self.mask * vec\n",
"\n",
" def vec2param(self, vec):\n",
" pointer = 0\n",
" for param in self.parameters():\n",
" param_len = np.cumprod(param.shape)[-1]\n",
" new_param = vec[pointer:pointer+param_len].reshape(param.shape)\n",
" param.data = new_param.data\n",
" pointer += param_len\n",
"\n",
"# A two layer residual network where the linear layers are sparse\n",
"class SparseMLP(torch.nn.Module):\n",
" def __init__(self, input_size, output_size, hidden_size=100):\n",
" super(SparseMLP, self).__init__()\n",
" self.linear1 = SparseLinear(input_size, hidden_size)\n",
" self.linear2 = SparseLinear(hidden_size, hidden_size)\n",
" self.linear3 = SparseLinear(hidden_size, output_size)\n",
" self.layers = [self.linear1, self.linear2, self.linear3]\n",
"\n",
" def forward(self, x):\n",
" h = torch.relu(self.linear1(x))\n",
" h = h + torch.relu(self.linear2(h))\n",
" h = self.linear3(h)\n",
" return h\n",
"\n",
" def get_layer_masks(self):\n",
" return [l.mask for l in self.layers]\n",
"\n",
" def set_layer_masks(self, new_masks):\n",
" for i, l in enumerate(self.layers):\n",
" l.update_mask(new_masks[i])\n",
"\n",
" def get_layer_vecs(self):\n",
" return [l.param2vec() for l in self.layers]\n",
"\n",
" def set_layer_vecs(self, vecs):\n",
" for i, l in enumerate(self.layers):\n",
" l.vec2param(vecs[i])"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"metadata": {
"id": "2hwmH2vIbHin"
},
"source": [
"Now we need a routine that takes the weights from the model and returns a mask that identifies the positions with the lowest magnitude. These will be the weights that we mask."
]
},
{
"cell_type": "code",
"metadata": {
"id": "Md2F9WDgYSqT"
},
"source": [
"# absolute weights -- absolute values of all the weights from the model in a long vector\n",
"# percent_sparse: how much to sparsify the model\n",
"def get_mask(absolute_weights, percent_sparse):\n",
" # TODO -- Write a function that returns a mask that has a zero\n",
" # everywhere for the lowest \"percent_sparse\" of the absolute weights.\n",
" # E.g. if absolute_weights contains [5,6,0,1,7] and we want percent_sparse of 40%,\n",
" # we would return [1,1,0,0,1]\n",
" # Remember that these are torch tensors and not numpy arrays\n",
" # Replace this function:\n",
" mask = torch.ones_like(scores)\n",
"\n",
"\n",
" return mask"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"metadata": {
"id": "z0McGMV-a3Xo"
},
"source": [
"## The prune-and-retrain cycle\n",
"This is the core method for finding a lottery ticket. We train a model for a fixed number of epochs, prune it, and then re-train and re-prune. We repeat this cycle until we achieve the desired level of sparsity."
]
},
{
"cell_type": "code",
"metadata": {
"id": "5idcbyA3Ylz_"
},
"source": [
"def find_lottery_ticket(model, dataset, args, sparsity_schedule, criteria_fn=None, **kwargs):\n",
"\n",
" criteria_fn = lambda init_params, final_params: final_params.abs()\n",
"\n",
" init_params = model.get_layer_vecs()\n",
" stats = {'train_losses':[], 'test_losses':[], 'train_accs':[], 'test_accs':[]}\n",
" models = []\n",
" for i, percent_sparse in enumerate(sparsity_schedule):\n",
"\n",
" # layer-wise pruning, where pruning heuristic is determined by criteria_fn\n",
" final_params = model.get_layer_vecs()\n",
" scores = [criteria_fn(ip, fp) for ip, fp in zip(init_params, final_params)]\n",
" masks = [get_mask(s, percent_sparse) for s in scores]\n",
"\n",
" # update model with mask and init parameters\n",
" model.set_layer_vecs(init_params)\n",
" model.set_layer_masks(masks)\n",
"\n",
" # training process\n",
" results = mnist1d.train_model(dataset, model, args)\n",
" model = results['checkpoints'][-1]\n",
"\n",
" # store stats\n",
" stats['train_losses'].append(results['train_losses'])\n",
" stats['test_losses'].append(results['test_losses'])\n",
" stats['train_accs'].append(results['train_acc'])\n",
" stats['test_accs'].append(results['test_acc'])\n",
"\n",
" # print progress\n",
" if (i+1) % 1 == 0:\n",
" print('\\tretrain #{}, sparsity {:.2f}, final_train_loss {:.3e}, max_acc {:.1f}, last_acc {:.1f}, mean_acc {:.1f}'\n",
" .format(i+1, percent_sparse, results['train_losses'][-1], np.max(results['test_acc']),\n",
" results['test_acc'][-1], np.mean(results['test_acc']) ))\n",
" models.append(copy.deepcopy(model))\n",
"\n",
" stats = {k: np.stack(v) for k, v in stats.items()}\n",
" return models, stats"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"metadata": {
"id": "m4lokvdD4DKI"
},
"source": [
"## Choose hyperparameters"
]
},
{
"cell_type": "code",
"metadata": {
"id": "OUe7-b-7Yl2c"
},
"source": [
"# train settings\n",
"model_args = mnist1d.get_model_args()\n",
"model_args.total_steps = 1501\n",
"model_args.hidden_size = 500\n",
"model_args.print_every = 5000 # print never\n",
"model_args.eval_every = 100\n",
"model_args.learning_rate = 2e-2\n",
"model_args.device = str('cpu')"
],
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"metadata": {
"id": "hVgDM5rI4J65"
},
"source": [
"Find the lottery ticket by repeatedly training and then pruning weights based on their magnitudes. We'll remove 1% of the weights each time. This is going to take half an hour or so. Go and have lunch or whatever."
]
},
{
"cell_type": "code",
"source": [
"# sparsity settings - we will train 100 models with progressively increasing sparsity\n",
"num_retrains = 100\n",
"sparsity_schedule = np.linspace(0,1.,num_retrains)\n",
"\n",
"print(\"Magnitude pruning\")\n",
"mnist1d.set_seed(model_args.seed)\n",
"model = SparseMLP(model_args.input_size, model_args.output_size, hidden_size=model_args.hidden_size)\n",
"\n",
"criteria_fn = lambda init_params, final_params: final_params.abs()\n",
"lott_models, lott_stats = find_lottery_ticket(model, data, model_args, sparsity_schedule, criteria_fn=criteria_fn, prune_print_every=1)"
],
"metadata": {
"id": "M25YpCuS1Gn0"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"test_losses = lott_stats['test_losses'][:,-1]\n",
"test_accs = lott_stats['test_accs'][:,-1]\n",
"\n",
"fig,ax = plt.subplots()\n",
"ax.plot(sparsity_schedule, test_losses,'r-')\n",
"ax.plot((sparsity_schedule[0], sparsity_schedule[-1]),(test_losses[0], test_losses[0]),'k--',label='dense')\n",
"ax.set_xlabel('Sparsity')\n",
"ax.set_ylabel('Loss')\n",
"ax.set_xlim(0,1)\n",
"ax.legend()\n",
"plt.show()\n",
"\n",
"fig,ax = plt.subplots()\n",
"ax.plot(sparsity_schedule, 100-test_accs,'r-')\n",
"ax.plot((sparsity_schedule[0], sparsity_schedule[-1]),(100-test_accs[0], 100-test_accs[0]),'k--',label='dense')\n",
"ax.set_xlabel('Sparsity')\n",
"ax.set_ylabel('Percent Error')\n",
"ax.set_xlim(0,1)\n",
"ax.set_ylim(0,100)\n",
"ax.legend()\n",
"plt.show()\n"
],
"metadata": {
"id": "TCs-kt6-3xHB"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"You should see that the test loss decreases and the errors decrease with more as the network gets sparser. The dashed line represents the original dense (unpruned) network. We have identified a simpler network that was \"inside\" the original network for which the results are superior. Of course if we make it too sparse, then it gets worse again.\n",
"\n",
"This phenomenon is explored much further in the original notebook by Sam Greydanus which can be found [here](https://github.com/greydanus/mnist1d)."
],
"metadata": {
"id": "CEj5_ZEHcRpw"
}
}
]
}

386
Notebooks/Chap20/20_4_Adversarial_Attacks.ipynb Normal file
View File

@@ -0,0 +1,386 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyP9amtzXsNWqkmiPUQgxzKV",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap20/20_4_Adversarial_Attacks.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# **Notebook 20.4: Adversarial attacks**\n",
"\n",
"This notebook builds uses the network for classification of MNIST from Notebook 10.5. The code is adapted from https://nextjournal.com/gkoehler/pytorch-mnist, and uses the fast gradient sign attack of [Goodfellow et al. (2015)](https://arxiv.org/abs/1412.6572). Having trained, the network, we search for adversarial examples -- inputs which look very similar to class A, but are mistakenly classified as class B. We do this by starting with a correctly classified example and perturbing it according to the gradients of the network so that the output changes.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions.\n"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"import torch\n",
"import torchvision\n",
"import torch.nn as nn\n",
"import torch.nn.functional as F\n",
"import torch.optim as optim\n",
"import matplotlib.pyplot as plt\n",
"import random"
],
"metadata": {
"id": "YrXWAH7sUWvU"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Run this once to load the train and test data straight into a dataloader class\n",
"# that will provide the batches\n",
"batch_size_train = 64\n",
"batch_size_test = 1000\n",
"train_loader = torch.utils.data.DataLoader(\n",
" torchvision.datasets.MNIST('/files/', train=True, download=True,\n",
" transform=torchvision.transforms.Compose([\n",
" torchvision.transforms.ToTensor(),\n",
" torchvision.transforms.Normalize(\n",
" (0.1307,), (0.3081,))\n",
" ])),\n",
" batch_size=batch_size_train, shuffle=True)\n",
"\n",
"test_loader = torch.utils.data.DataLoader(\n",
" torchvision.datasets.MNIST('/files/', train=False, download=True,\n",
" transform=torchvision.transforms.Compose([\n",
" torchvision.transforms.ToTensor(),\n",
" torchvision.transforms.Normalize(\n",
" (0.1307,), (0.3081,))\n",
" ])),\n",
" batch_size=batch_size_test, shuffle=True)"
],
"metadata": {
"id": "wScBGXXFVadm"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Let's draw some of the training data\n",
"examples = enumerate(test_loader)\n",
"batch_idx, (example_data, example_targets) = next(examples)\n",
"\n",
"fig = plt.figure()\n",
"for i in range(6):\n",
" plt.subplot(2,3,i+1)\n",
" plt.tight_layout()\n",
" plt.imshow(example_data[i][0], cmap='gray', interpolation='none')\n",
" plt.title(\"Ground Truth: {}\".format(example_targets[i]))\n",
" plt.xticks([])\n",
" plt.yticks([])\n",
"plt.show()"
],
"metadata": {
"id": "8bKADvLHbiV5"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Define the network. This is a more typical way to define a network than the sequential structure. We define a class for the network, and define the parameters in the constructor. Then we use a function called forward to actually run the network. It's easy to see how you might use residual connections in this format."
],
"metadata": {
"id": "_sFvRDGrl4qe"
}
},
{
"cell_type": "code",
"source": [
"from os import X_OK\n",
"\n",
"class Net(nn.Module):\n",
" def __init__(self):\n",
" super(Net, self).__init__()\n",
" self.conv1 = nn.Conv2d(1, 10, kernel_size=5)\n",
" self.conv2 = nn.Conv2d(10, 20, kernel_size=5)\n",
" self.drop = nn.Dropout2d()\n",
" self.fc1 = nn.Linear(320, 50)\n",
" self.fc2 = nn.Linear(50, 10)\n",
"\n",
" def forward(self, x):\n",
" x = self.conv1(x)\n",
" x = F.max_pool2d(x,2)\n",
" x = F.relu(x)\n",
" x = self.conv2(x)\n",
" x = self.drop(x)\n",
" x = F.max_pool2d(x,2)\n",
" x = F.relu(x)\n",
" x = x.flatten(1)\n",
" x = F.relu(self.fc1(x))\n",
" x = self.fc2(x)\n",
" x = F.log_softmax(x)\n",
" return x"
],
"metadata": {
"id": "EQkvw2KOPVl7"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# He initialization of weights\n",
"def weights_init(layer_in):\n",
" if isinstance(layer_in, nn.Linear):\n",
" nn.init.kaiming_uniform_(layer_in.weight)\n",
" layer_in.bias.data.fill_(0.0)"
],
"metadata": {
"id": "qWZtkCZcU_dg"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Create network\n",
"model = Net()\n",
"# Initialize model weights\n",
"model.apply(weights_init)\n",
"# Define optimizer\n",
"optimizer = optim.SGD(model.parameters(), lr=0.01, momentum=0.5)"
],
"metadata": {
"id": "FslroPJJffrh"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Main training routine\n",
"def train(epoch):\n",
" model.train()\n",
" # Get each\n",
" for batch_idx, (data, target) in enumerate(train_loader):\n",
" optimizer.zero_grad()\n",
" output = model(data)\n",
" loss = F.nll_loss(output, target)\n",
" loss.backward()\n",
" optimizer.step()\n",
" # Store results\n",
" if batch_idx % 10 == 0:\n",
" print('Train Epoch: {} [{}/{}]\\tLoss: {:.6f}'.format(\n",
" epoch, batch_idx * len(data), len(train_loader.dataset), loss.item()))"
],
"metadata": {
"id": "xKQd9PzkQ766"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Run on test data\n",
"def test():\n",
" model.eval()\n",
" test_loss = 0\n",
" correct = 0\n",
" with torch.no_grad():\n",
" for data, target in test_loader:\n",
" output = model(data)\n",
" test_loss += F.nll_loss(output, target, size_average=False).item()\n",
" pred = output.data.max(1, keepdim=True)[1]\n",
" correct += pred.eq(target.data.view_as(pred)).sum()\n",
" test_loss /= len(test_loader.dataset)\n",
" print('\\nTest set: Avg. loss: {:.4f}, Accuracy: {}/{} ({:.0f}%)\\n'.format(\n",
" test_loss, correct, len(test_loader.dataset),\n",
" 100. * correct / len(test_loader.dataset)))"
],
"metadata": {
"id": "Byn-f7qWRLxX"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Get initial performance\n",
"test()\n",
"# Train for three epochs\n",
"n_epochs = 3\n",
"for epoch in range(1, n_epochs + 1):\n",
" train(epoch)\n",
" test()"
],
"metadata": {
"id": "YgLaex1pfhqz"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Run network on data we got before and show predictions\n",
"output = model(example_data)\n",
"\n",
"fig = plt.figure()\n",
"for i in range(6):\n",
" plt.subplot(2,3,i+1)\n",
" plt.tight_layout()\n",
" plt.imshow(example_data[i][0], cmap='gray', interpolation='none')\n",
" plt.title(\"Prediction: {}\".format(\n",
" output.data.max(1, keepdim=True)[1][i].item()))\n",
" plt.xticks([])\n",
" plt.yticks([])\n",
"plt.show()"
],
"metadata": {
"id": "o7fRUAy9Se1B"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"This is the code that does the adversarial attack. It is adapted from [here](https://pytorch.org/tutorials/beginner/fgsm_tutorial.html). It is an example of the fast gradient sign method (FGSM), which modifies the data by\n",
"\n",
"\n",
"\n",
"* Calculating the derivative $\\partial L/\\partial \\mathbf{x}$ of the loss $L$ with respect to the input data $\\mathbf{x}$.\n",
"* Finds the sign of the gradient at each point (making a tensor the same size as $\\mathbf{x}$ with a one where it was positive and minus one where it was negative. \n",
"* Multiplying this vector by $\\epsilon$ and adding it back to the original data\n",
"\n",
"\n"
],
"metadata": {
"id": "EabuoMdP32Hd"
}
},
{
"cell_type": "code",
"source": [
"# FGSM attack code.\n",
"def fgsm_attack(x, epsilon, dLdx):\n",
" # TODO -- write this function\n",
" # Get the sign of the gradient\n",
" # Add epsilon times the size of gradient to x\n",
" # Replace this line\n",
" x_modified = torch.zeros_like(x)\n",
"\n",
" # Return the perturbed image\n",
" return x_modified"
],
"metadata": {
"id": "gAX7tnld46q1"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"no_examples = 3\n",
"epsilon = 0.5\n",
"for i in range(no_examples):\n",
" # Reset gradients\n",
" optimizer.zero_grad()\n",
"\n",
" # Get the i'th data example\n",
" x = example_data[i,:,:,:]\n",
" # Add an extra dimension back to the beginning\n",
" x= x[None, :,:,:]\n",
" x.requires_grad = True\n",
" # Get the i'th target\n",
" y = torch.ones(1, dtype=torch.long) * example_targets[i]\n",
"\n",
" # Run the model\n",
" output = model(x)\n",
" # Compute the loss\n",
" loss = F.nll_loss(output, y)\n",
" # Back propagate\n",
" loss.backward()\n",
"\n",
" # Collect ``datagrad``\n",
" dLdx = x.grad.data\n",
"\n",
" # Call FGSM Attack\n",
" x_prime = fgsm_attack(x, epsilon, dLdx)\n",
"\n",
" # Re-classify the perturbed image\n",
" output_prime = model(x_prime)\n",
"\n",
" x = x.detach().numpy()\n",
" fig = plt.figure()\n",
" plt.subplot(1,2,1)\n",
" plt.tight_layout()\n",
" plt.imshow(x[0][0], cmap='gray', interpolation='none')\n",
" plt.title(\"Original Prediction: {}\".format(\n",
" output.data.max(1, keepdim=True)[1][0].item()))\n",
" plt.xticks([])\n",
" plt.yticks([])\n",
"\n",
" plt.subplot(1,2,2)\n",
" plt.tight_layout()\n",
" plt.imshow(x_prime[0][0].detach().numpy(), cmap='gray', interpolation='none')\n",
" plt.title(\"Perturbed Prediction: {}\".format(\n",
" output_prime.data.max(1, keepdim=True)[1][0].item()))\n",
" plt.xticks([])\n",
" plt.yticks([])\n",
"\n",
"plt.show()"
],
"metadata": {
"id": "AuNTYWboufbm"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Although we have only added a small amount of noise, the model is fooled into thinking that these images come from a different class.\n",
"\n",
"TODO -- Modify the attack so that it iteratively perturbs the data. i.e., so we take a small step epsilon, then re-calculate the gradient and take another small step according to the new gradient signs."
],
"metadata": {
"id": "vFXWK826HPQ8"
}
}
]
}

441
Notebooks/Chap21/21_1_Bias_Mitigation.ipynb Normal file
View File

@@ -0,0 +1,441 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyNQPfTDV6PFG7Ctcl+XVNlz",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap21/21_1_Bias_Mitigation.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# **Notebook 21.1: Bias mitigation**\n",
"\n",
"This notebook investigates a post-processing method for bias mitigation (see figure 21.2 in the book). It based on this [blog](https://www.borealisai.com/research-blogs/tutorial1-bias-and-fairness-ai/) that I wrote for Borealis AI in 2019, which itself was derived from [this blog](https://research.google.com/bigpicture/attacking-discrimination-in-ml/) by Wattenberg, Viégas, and Hardt.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions.\n"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import matplotlib.pyplot as plt"
],
"metadata": {
"id": "yC_LpiJqZXEL"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"# Worked example: loans\n",
"\n",
"Consider the example of an algorithm $c=\\mbox{f}[\\mathbf{x},\\boldsymbol\\phi]$ that predicts credit rating scores $c$ for loan decisions. There are two pools of loan applicants identified by the variable $p\\in\\{0,1\\}$ that well describe as the blue and yellow populations. We assume that we are given historical data, so we know both the credit rating and whether the applicant actually defaulted on the loan ($y=0$) or\n",
" repaid it ($y=1$).\n",
"\n",
"We can now think of four groups of data corresponding to (i) the blue and yellow populations and (ii) whether they did or did not repay the loan. For each of these four groups we have a distribution of credit ratings (figure 1). In an ideal world, the two distributions for the yellow population would be exactly the same as those for the blue population. However, as figure 1 shows, this is clearly not the case here."
],
"metadata": {
"id": "2FYo1dWGZXgg"
}
},
{
"cell_type": "code",
"source": [
"# Class that can describe interesting curve shapes based on the input parameters\n",
"# Details don't matter\n",
"class FreqCurve:\n",
" def __init__(self, weight, mean1, mean2, sigma1, sigma2, prop):\n",
" self.mean1 = mean1\n",
" self.mean2 = mean2\n",
" self.sigma1 = sigma1\n",
" self.sigma2 = sigma2\n",
" self.prop = prop\n",
" self.weight = weight\n",
"\n",
" def freq(self, x):\n",
" return self.weight * self.prop * np.exp(-0.5 * (x-self.mean1) * (x-self.mean1) / (self.sigma1 * self.sigma1)) \\\n",
" * 1.0 / np.sqrt(2*np.pi*self.sigma1*self.sigma1) \\\n",
" + self.weight * (1-self.prop) * np.exp(-0.5 * (x-self.mean2) * (x-self.mean2) / (self.sigma2 * self.sigma2)) \\\n",
" * 1.0 / np.sqrt(2*np.pi*self.sigma2*self.sigma2)\n"
],
"metadata": {
"id": "O_0gGH9hZcjo"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"credit_scores = np.arange(-4,4,0.01)\n",
"freq_y0_p0 = FreqCurve(800, -1.5, -2.5, 0.8, 0.6, 0.6).freq(credit_scores)\n",
"freq_y1_p0 = FreqCurve(500, 0.1, 0.7, 1.5, 0.8, 0.4 ).freq(credit_scores)\n",
"freq_y0_p1 = FreqCurve(400, 0.2, -0.1, 0.8, 0.6, 0.3).freq(credit_scores)\n",
"freq_y1_p1 = FreqCurve(650, 0.6, 1.6, 1.2, 0.7, 0.6 ).freq(credit_scores)\n"
],
"metadata": {
"id": "Bkp7vffBbrNW"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"\n",
"fig = plt.figure\n",
"ax = plt.subplot(2,2,1)\n",
"plt.tight_layout()\n",
"ax.plot(credit_scores, freq_y0_p0, 'b--', label='y=0 (defaulted)')\n",
"ax.plot(credit_scores, freq_y1_p0, 'b-', label='y=1 (repaid)')\n",
"ax.set_xlim(-4,4)\n",
"ax.set_ylim(0,500)\n",
"ax.set_xlabel('Credit score, $c$')\n",
"ax.set_ylabel('Frequency')\n",
"ax.set_title('Population p=0')\n",
"ax.legend()\n",
"\n",
"ax = plt.subplot(2,2,2)\n",
"plt.tight_layout()\n",
"ax.plot(credit_scores, freq_y0_p1, 'y--', label='y=0 (defaulted)')\n",
"ax.plot(credit_scores, freq_y1_p1, 'y-', label='y=1 (repaid)')\n",
"ax.set_xlim(-4,4)\n",
"ax.set_ylim(0,500)\n",
"ax.set_xlabel('Credit score, $c$')\n",
"ax.set_ylabel('Frequency')\n",
"ax.set_title('Population p=1')\n",
"ax.legend()\n",
"\n",
"plt.show()"
],
"metadata": {
"id": "Jf7uqyRyhVdS"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Why might the distributions for blue and yellow populations be different? It could be that the behaviour of the populations is identical, but the credit rating algorithm is biased; it may favor one population over another or simply be more noisy for one group. Alternatively, it could be that that the populations genuinely behave differently. In practice, the differences in blue and yellow distributions are probably attributable to a combination of these factors.\n",
"\n",
"Lets assume that we cant retrain the credit score prediction algorithm; our job is to adjudicate whether each individual is refused the loan ($\\hat{y}=0$)\n",
" or granted it ($\\hat{y}=1$). Since we only have the credit score\n",
" to go on, the best we can do is to assign different thresholds $\\tau_{1}$\n",
" and $\\tau_{2}$\n",
" for the blue and yellow populations so that the loan is granted if the credit score $c$ generated by the model exceeds $\\tau_0$ for the blue population and $\\tau_1$ for the yellow population."
],
"metadata": {
"id": "CfZ-srQtmff2"
}
},
{
"cell_type": "markdown",
"source": [
"Now let's investiate how to set these thresholds to fulfil different criteria."
],
"metadata": {
"id": "569oU1OtoFz8"
}
},
{
"cell_type": "markdown",
"source": [
"# Blindness to protected attribute\n",
"\n",
"We'll first do the simplest possible thing. We'll choose the same threshold for both blue and yellow populations so that $\\tau_0$ = $\\tau_1$. Basically, we'll ignore what we know about the group membership. Let's see what the ramifications of that."
],
"metadata": {
"id": "bE7yPyuWoSUy"
}
},
{
"cell_type": "code",
"source": [
"# Set the thresholds\n",
"tau0 = tau1 = 0.0"
],
"metadata": {
"id": "WIG8I-LvoFBY"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"def compute_probability_get_loan(credit_scores, frequencies, threshold):\n",
" # TODO - Write this function\n",
" # Return the probability that someone from this group loan based on the frequencies of each\n",
" # credit score for this group\n",
" # Replace this line:\n",
" prob = 0.5\n",
"\n",
"\n",
" return prob"
],
"metadata": {
"id": "2EvkCvVBiCBn"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"First let's see what the overall probability of getting the loan is for the yellow and blue populations."
],
"metadata": {
"id": "AGT40q6_qfpv"
}
},
{
"cell_type": "code",
"source": [
"pr_get_loan_p0 = compute_probability_get_loan(credit_scores, freq_y0_p0+freq_y1_p0, tau0)\n",
"pr_get_loan_p1 = compute_probability_get_loan(credit_scores, freq_y0_p1+freq_y1_p1, tau1)\n",
"print(\"Probability blue group gets loan = %3.3f\"%(pr_get_loan_p0))\n",
"print(\"Probability yellow group gets loan = %3.3f\"%(pr_get_loan_p1))"
],
"metadata": {
"id": "4nI-PR_wqWj6"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Now let's plot a receiver operating characteristic (ROC) curve. This shows the rate of true positives $Pr(\\hat{y}=1|y=1)$ (people who got loan and paid it back) and false alarms $Pr(\\hat{y}=1|y=0)$ (people who got the loan but didn't pay it back) for all possible thresholds."
],
"metadata": {
"id": "G2pEa6h6sIyu"
}
},
{
"cell_type": "code",
"source": [
"def plot_roc(credit_scores, freq_y0_p0, freq_y1_p0, freq_y0_p1, freq_y1_p1, tau0, tau1):\n",
" true_positives_p0 = np.zeros_like(credit_scores)\n",
" false_alarms_p0 = np.zeros_like(credit_scores)\n",
" true_positives_p1 = np.zeros_like(credit_scores)\n",
" false_alarms_p1 = np.zeros_like(credit_scores)\n",
" for i in range(len(credit_scores)):\n",
" true_positives_p0[i] = compute_probability_get_loan(credit_scores, freq_y1_p0, credit_scores[i])\n",
" true_positives_p1[i] = compute_probability_get_loan(credit_scores, freq_y1_p1, credit_scores[i])\n",
" false_alarms_p0[i] = compute_probability_get_loan(credit_scores, freq_y0_p0, credit_scores[i])\n",
" false_alarms_p1[i] = compute_probability_get_loan(credit_scores, freq_y0_p1, credit_scores[i])\n",
"\n",
" true_positives_p0_tau0 = compute_probability_get_loan(credit_scores, freq_y1_p0, tau0)\n",
" true_positives_p1_tau1 = compute_probability_get_loan(credit_scores, freq_y1_p1, tau1)\n",
" false_alarms_p0_tau0 = compute_probability_get_loan(credit_scores, freq_y0_p0, tau0)\n",
" false_alarms_p1_tau1 = compute_probability_get_loan(credit_scores, freq_y0_p1, tau1)\n",
"\n",
" fig, ax = plt.subplots()\n",
" ax.plot(false_alarms_p0, true_positives_p0, 'b-')\n",
" ax.plot(false_alarms_p1, true_positives_p1, 'y-')\n",
" ax.plot(false_alarms_p0_tau0, true_positives_p0_tau0,'bo')\n",
" ax.plot(false_alarms_p1_tau1, true_positives_p1_tau1,'yo')\n",
" ax.set_xlim(0,1)\n",
" ax.set_ylim(0,1)\n",
" ax.set_xlabel('False alarms $Pr(\\hat{y}=1|y=0)$')\n",
" ax.set_ylabel('True positives $Pr(\\hat{y}=1|y=1)$')\n",
" ax.set_aspect('equal')\n",
"\n",
" plt.show()"
],
"metadata": {
"id": "2C7kNt3hqwiu"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"plot_roc(credit_scores, freq_y0_p0, freq_y1_p0, freq_y0_p1, freq_y1_p1, tau0, tau1)"
],
"metadata": {
"id": "h3OOQeTsv8uS"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"On this plot, the true positive and false alarm rate for the particular thresholds ($\\tau_0=\\tau_{1}=0$) that we chose are indicated by the circles.\n",
"\n",
"This criterion is clearly not great. The blue and yellow groups get given loans at different rates overall, and (for this threshold), the false alarms and true positives are also different, so it's not even fair when we consider whether the loans really were paid back. \n",
"\n",
"TODO -- investigate setting a different threshold $\\tau_{0}=\\tau_{1}$. Is it possible to make the overall rates that loans are given the same? Is it possible to make the false alarm rates the same? Is it possible to make the true positive rates the same?"
],
"metadata": {
"id": "UCObTsa57uuC"
}
},
{
"cell_type": "markdown",
"source": [
"# Equality of odds\n",
"\n",
"This definition of fairness proposes that the false positive and true positive rates should be the same for both populations. This also sounds reasonable, but the ROC curve shows that it is not possible for this example. There is no combination of thresholds that can achieve this because the ROC curves do not intersect. Even if they did, we would be stuck giving loans based on the particular false positive and true positive rates at the intersection which might not be desirable."
],
"metadata": {
"id": "Yhrxv5AQ-PWA"
}
},
{
"cell_type": "markdown",
"source": [
"Demographic parity\n",
"\n",
"The thresholds can be chosen so that the same proportion of each group are classified as $\\hat{y}=1$ and given loans. We make an equal number of loans to each group despite the different tendencies of each to repay. This has the disadvantage that the true positive and false positive rates might be completely different in different populations. From the perspective of the lender, it is desirable to give loans in proportion to peoples ability to pay them back. From the perspective of an individual in a more reliable group, it may seem unfair that the other group gets offered the same number of loans despite the fact they are less reliable."
],
"metadata": {
"id": "l6yb8vjX-gdi"
}
},
{
"cell_type": "code",
"source": [
"# TO DO -- try to change the two thresholds so the overall probability of getting the loan is 0.6 for each group\n",
"# Change the values in these lines\n",
"tau0 = 0.3\n",
"tau1 = -0.1\n",
"\n",
"\n",
"\n",
"# Compute overall probability of getting loan\n",
"pr_get_loan_p0 = compute_probability_get_loan(credit_scores, freq_y0_p0+freq_y1_p0, tau0)\n",
"pr_get_loan_p1 = compute_probability_get_loan(credit_scores, freq_y0_p1+freq_y1_p1, tau1)\n",
"print(\"Probability blue group gets loan = %3.3f\"%(pr_get_loan_p0))\n",
"print(\"Probability yellow group gets loan = %3.3f\"%(pr_get_loan_p1))"
],
"metadata": {
"id": "syjZ2fn5wC9-"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"This is good, because now both groups get roughly the same amount of loans. But hold on... let's look at the ROC curve:"
],
"metadata": {
"id": "5QrtvZZlHCJy"
}
},
{
"cell_type": "code",
"source": [
"plot_roc(credit_scores, freq_y0_p0, freq_y1_p0, freq_y0_p1, freq_y1_p1, tau0, tau1)"
],
"metadata": {
"id": "VApyl_58GUQb"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"The blue dot is waaay above the yellow dot. The proportion of people who are given a load and do pay it back from the blue population is much higher than that from the yellow population. From another perspective, that's unfair... it seems like the yellow population are 'allowed' to default more often than the blue. This leads to another possibility."
],
"metadata": {
"id": "_GgX_b6yIE4W"
}
},
{
"cell_type": "markdown",
"source": [
"# Equal opportunity:\n",
"\n",
"The thresholds are chosen so that so that the true positive rate is is the same for both population. Of the people who pay back the loan, the same proportion are offered credit in each group. In terms of the two ROC curves, it means choosing thresholds so that the vertical position on each curve is the same without regard for the horizontal position."
],
"metadata": {
"id": "WDnaqetXHhlv"
}
},
{
"cell_type": "code",
"source": [
"# TO DO -- try to change the two thresholds so the true positive are 0.8 for each group\n",
"# Change the values in these lines so that both points on the curves have a height of 0.8\n",
"tau0 = -0.1\n",
"tau1 = -0.7\n",
"\n",
"\n",
"plot_roc(credit_scores, freq_y0_p0, freq_y1_p0, freq_y0_p1, freq_y1_p1, tau0, tau1)"
],
"metadata": {
"id": "zEN6HGJ7HJAZ"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"This seems fair -- people who are given loans default at the same rate (20%) for both groups. But hold on... let's look at the overall loan rate between the two populations:"
],
"metadata": {
"id": "JsyW0pBGJ24b"
}
},
{
"cell_type": "code",
"source": [
"# Compute overall probability of getting loan\n",
"pr_get_loan_p0 = compute_probability_get_loan(credit_scores, freq_y0_p0+freq_y1_p0, tau0)\n",
"pr_get_loan_p1 = compute_probability_get_loan(credit_scores, freq_y0_p1+freq_y1_p1, tau1)\n",
"print(\"Probability blue group gets loan = %3.3f\"%(pr_get_loan_p0))\n",
"print(\"Probability yellow group gets loan = %3.3f\"%(pr_get_loan_p1))"
],
"metadata": {
"id": "2a5PXHeNJDjg"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"The conclusion from all this is that (i) definitions of fairness are quite subtle and (ii) it's not possible to satisfy them all simultaneously."
],
"metadata": {
"id": "tZTM7N6jKC7q"
}
}
]
}

412
Notebooks/Chap21/21_2_Explainability.ipynb Normal file
View File

@@ -0,0 +1,412 @@
{
"nbformat": 4,
"nbformat_minor": 0,
"metadata": {
"colab": {
"provenance": [],
"authorship_tag": "ABX9TyOLMPuSWpvv8BfyPV36RuJP",
"include_colab_link": true
},
"kernelspec": {
"name": "python3",
"display_name": "Python 3"
},
"language_info": {
"name": "python"
}
},
"cells": [
{
"cell_type": "markdown",
"metadata": {
"id": "view-in-github",
"colab_type": "text"
},
"source": [
"<a href=\"https://colab.research.google.com/github/udlbook/udlbook/blob/main/Notebooks/Chap21/21_2_Explainability.ipynb\" target=\"_parent\"><img src=\"https://colab.research.google.com/assets/colab-badge.svg\" alt=\"Open In Colab\"/></a>"
]
},
{
"cell_type": "markdown",
"source": [
"# **Notebook 21.2: Explainability**\n",
"\n",
"This notebook investigates the LIME explainability method as depicted in figure 21.3 of the book.\n",
"\n",
"Work through the cells below, running each cell in turn. In various places you will see the words \"TO DO\". Follow the instructions at these places and make predictions about what is going to happen or write code to complete the functions.\n",
"\n",
"Contact me at udlbookmail@gmail.com if you find any mistakes or have any suggestions.\n"
],
"metadata": {
"id": "t9vk9Elugvmi"
}
},
{
"cell_type": "code",
"source": [
"import numpy as np\n",
"import matplotlib.pyplot as plt\n",
"import numpy.matlib\n",
"from matplotlib.colors import ListedColormap"
],
"metadata": {
"id": "yC_LpiJqZXEL"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"First we'll build a black box model for predicting a credit score. This simulates a neural network. It takes four inputs $x1,x2,x3,x4$ in a column vector and it returns a value $y$. Let's assume that if the output $y$ is greater than 0 then you get the loan, and if the output is less than 0 then you don't get the zone."
],
"metadata": {
"id": "WM6mq9KNit3j"
}
},
{
"cell_type": "code",
"source": [
"# Details of this not important -- a hacky thing that takes four inputs and returns\n",
"# a scalar output\n",
"class BlackBoxModel:\n",
" def __init__(self):\n",
" self.n_dim = 4\n",
" self.n_points = 10\n",
" self.means = np.random.uniform(size=(self.n_dim, self.n_points))\n",
" self.stds = np.random.uniform(size=(self.n_dim,self.n_points))+0.1\n",
" self.values = np.random.normal(size=(self.n_points))/10\n",
" self.values = self.values - np.mean(self.values)\n",
"\n",
"\n",
" def intensity(self, x, mean, std, value):\n",
"\n",
" dist = (x-np.matlib.repmat(mean,1,x.shape[1])) / np.matlib.repmat(std,1,x.shape[1])\n",
" out = value * np.exp(-np.sum(dist*dist,axis=0))\n",
" out = out[None,:]\n",
" return out\n",
"\n",
"\n",
" def get_output(self,x):\n",
" y = np.zeros((1,x.shape[1]))\n",
" t_vals = np.arange(0, self.n_points-1, 0.01)\n",
" for t in t_vals:\n",
" i = np.floor(t)\n",
" prop = t-i\n",
" i = int(i)\n",
" y = y+ prop * self.intensity(x, self.means[:,[i]], self.stds[:,[i]], self.values[i])\n",
" y = y+ (1-prop) * self.intensity(x,self.means[:,[i+1]], self.stds[:,[i+1]], self.values[i+1])\n",
" y = np.clip(y,-10,10)\n",
" return y"
],
"metadata": {
"id": "rt4FS42dIa9_"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"# Code to draw 2D slide through the four dimensional function\n",
"# Again, you don't really need to read this.\n",
"def draw_2D_slice(model, dim1, dim2, first_other_dim_value = 0.5, second_other_dim_value = 0.6):\n",
"\n",
" #Create pretty colormap as in book\n",
" my_colormap_vals_hex =('2a0902', '2b0a03', '2c0b04', '2d0c05', '2e0c06', '2f0d07', '300d08', '310e09', '320f0a', '330f0b', '34100b', '35110c', '36110d', '37120e', '38120f', '39130f', '3a1410', '3b1411', '3c1511', '3d1612', '3e1613', '3f1713', '401714', '411814', '421915', '431915', '451a16', '461b16', '471b17', '481c17', '491d18', '4a1d18', '4b1e19', '4c1f19', '4d1f1a', '4e201b', '50211b', '51211c', '52221c', '53231d', '54231d', '55241e', '56251e', '57261f', '58261f', '592720', '5b2821', '5c2821', '5d2922', '5e2a22', '5f2b23', '602b23', '612c24', '622d25', '632e25', '652e26', '662f26', '673027', '683027', '693128', '6a3229', '6b3329', '6c342a', '6d342a', '6f352b', '70362c', '71372c', '72372d', '73382e', '74392e', '753a2f', '763a2f', '773b30', '783c31', '7a3d31', '7b3e32', '7c3e33', '7d3f33', '7e4034', '7f4134', '804235', '814236', '824336', '834437', '854538', '864638', '874739', '88473a', '89483a', '8a493b', '8b4a3c', '8c4b3c', '8d4c3d', '8e4c3e', '8f4d3f', '904e3f', '924f40', '935041', '945141', '955242', '965343', '975343', '985444', '995545', '9a5646', '9b5746', '9c5847', '9d5948', '9e5a49', '9f5a49', 'a05b4a', 'a15c4b', 'a35d4b', 'a45e4c', 'a55f4d', 'a6604e', 'a7614e', 'a8624f', 'a96350', 'aa6451', 'ab6552', 'ac6552', 'ad6653', 'ae6754', 'af6855', 'b06955', 'b16a56', 'b26b57', 'b36c58', 'b46d59', 'b56e59', 'b66f5a', 'b7705b', 'b8715c', 'b9725d', 'ba735d', 'bb745e', 'bc755f', 'bd7660', 'be7761', 'bf7862', 'c07962', 'c17a63', 'c27b64', 'c27c65', 'c37d66', 'c47e67', 'c57f68', 'c68068', 'c78169', 'c8826a', 'c9836b', 'ca846c', 'cb856d', 'cc866e', 'cd876f', 'ce886f', 'ce8970', 'cf8a71', 'd08b72', 'd18c73', 'd28d74', 'd38e75', 'd48f76', 'd59077', 'd59178', 'd69279', 'd7937a', 'd8957b', 'd9967b', 'da977c', 'da987d', 'db997e', 'dc9a7f', 'dd9b80', 'de9c81', 'de9d82', 'df9e83', 'e09f84', 'e1a185', 'e2a286', 'e2a387', 'e3a488', 'e4a589', 'e5a68a', 'e5a78b', 'e6a88c', 'e7aa8d', 'e7ab8e', 'e8ac8f', 'e9ad90', 'eaae91', 'eaaf92', 'ebb093', 'ecb295', 'ecb396', 'edb497', 'eeb598', 'eeb699', 'efb79a', 'efb99b', 'f0ba9c', 'f1bb9d', 'f1bc9e', 'f2bd9f', 'f2bfa1', 'f3c0a2', 'f3c1a3', 'f4c2a4', 'f5c3a5', 'f5c5a6', 'f6c6a7', 'f6c7a8', 'f7c8aa', 'f7c9ab', 'f8cbac', 'f8ccad', 'f8cdae', 'f9ceb0', 'f9d0b1', 'fad1b2', 'fad2b3', 'fbd3b4', 'fbd5b6', 'fbd6b7', 'fcd7b8', 'fcd8b9', 'fcdaba', 'fddbbc', 'fddcbd', 'fddebe', 'fddfbf', 'fee0c1', 'fee1c2', 'fee3c3', 'fee4c5', 'ffe5c6', 'ffe7c7', 'ffe8c9', 'ffe9ca', 'ffebcb', 'ffeccd', 'ffedce', 'ffefcf', 'fff0d1', 'fff2d2', 'fff3d3', 'fff4d5', 'fff6d6', 'fff7d8', 'fff8d9', 'fffada', 'fffbdc', 'fffcdd', 'fffedf', 'ffffe0')\n",
" my_colormap_vals_dec = np.array([int(element,base=16) for element in my_colormap_vals_hex])\n",
" r = np.floor(my_colormap_vals_dec/(256*256))\n",
" g = np.floor((my_colormap_vals_dec - r *256 *256)/256)\n",
" b = np.floor(my_colormap_vals_dec - r * 256 *256 - g * 256)\n",
" my_colormap_vals = np.vstack((r,g,b)).transpose()/255.0\n",
" my_colormap = ListedColormap(my_colormap_vals)\n",
"\n",
" x1_vals = np.arange(0.0, 1.0, 0.01)\n",
" x2_vals = np.arange(0.0, 1.0, 0.01)\n",
" x1_mesh, x2_mesh = np.meshgrid(x1_vals,x2_vals)\n",
" n_vals = x1_mesh.shape[0]\n",
"\n",
" x1 = np.reshape(x1_mesh,(1,n_vals*n_vals))\n",
" x2 = np.reshape(x2_mesh,(1,n_vals*n_vals))\n",
"\n",
" x = np.ones((4,n_vals*n_vals))\n",
" x[dim1,:] = x1\n",
" x[dim2,:] = x2\n",
" if((dim1==0 and dim2 ==1) or (dim1==1 and dim2 ==0)):\n",
" x[2,:] = x[2,:] * first_other_dim_value\n",
" x[3,:] = x[3,:] * second_other_dim_value\n",
" message = \"$x_{2}$ = %3.3f, $x_3$=%3.3f\"%(first_other_dim_value, second_other_dim_value)\n",
" if((dim1==0 and dim2 ==2) or (dim1==2 and dim2 ==0)):\n",
" x[1,:] = x[1,:] * first_other_dim_value\n",
" x[3,:] = x[3,:] * second_other_dim_value\n",
" message = \"$x_{1}$ = %3.3f, $x_3$=%3.3f\"%(first_other_dim_value, second_other_dim_value)\n",
" if((dim1==0 and dim2 ==3) or (dim1==3 and dim2 ==0)):\n",
" x[1,:] = x[1,:] * first_other_dim_value\n",
" x[2,:] = x[2,:] * second_other_dim_value\n",
" message = \"$x_{1}$ = %3.3f, $x_2$=%3.3f\"%(first_other_dim_value, second_other_dim_value)\n",
" if((dim1==1 and dim2 ==2) or (dim1==2 and dim2 ==1)):\n",
" x[0,:] = x[0,:] * first_other_dim_value\n",
" x[3,:] = x[3,:] * second_other_dim_value\n",
" message = \"$x_{0}$ = %3.3f, $x_3$=%3.3f\"%(first_other_dim_value, second_other_dim_value)\n",
" if((dim1==1 and dim2 ==3) or (dim1==3 and dim2 ==1)):\n",
" x[0,:] = x[0,:] * first_other_dim_value\n",
" x[2,:] = x[2,:] * second_other_dim_value\n",
" message = \"$x_{0}$ = %3.3f, $x_2$=%3.3f\"%(first_other_dim_value, second_other_dim_value)\n",
" if((dim1==2 and dim2 ==3) or (dim1==3 and dim2 ==2)):\n",
" x[0,:] = x[0,:] * first_other_dim_value\n",
" x[1,:] = x[1,:] * second_other_dim_value\n",
" message = \"$x_{0}$ = %3.3f, $x_1$=%3.3f\"%(first_other_dim_value, second_other_dim_value)\n",
"\n",
" y = model.get_output(x)\n",
" y[0,0] = -10; y[0,1]=10 # Hack the first two values so we see whole range of colormap\n",
" y_mesh = np.reshape(y,(n_vals, n_vals))\n",
"\n",
"\n",
" fig, ax = plt.subplots()\n",
" fig.set_size_inches(7,7)\n",
" pos = ax.contourf(x1_mesh, x2_mesh, y_mesh, levels=256 ,cmap = my_colormap, vmin=-10,vmax=10.0)\n",
" ax.set_xlabel('Dimension x%d'%dim1);ax.set_ylabel('Dimension x%d'%dim2)\n",
" ax.set_title(message)\n",
" levels = np.array([0])\n",
" ax.contour(x1_mesh, x2_mesh, y_mesh, levels, cmap=my_colormap)\n",
" cb = fig.colorbar(pos)\n",
" cb.set_ticks((-10,-5,0,5,10))\n",
" plt.show()"
],
"metadata": {
"id": "g0sosSU4RdU3"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Create an instance of our model"
],
"metadata": {
"id": "RlHjBpcyjcw4"
}
},
{
"cell_type": "code",
"source": [
"np.random.seed(3)\n",
"model = BlackBoxModel()"
],
"metadata": {
"id": "-JXgQD4oT3J1"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"The four inputs to the model might represent the four inputs measures of our debt, age, income etc, and the output represents the credit score.\n",
"\n",
"As a responsible model owner, we want to understand our model and make sure that it is doing something sensible. \n",
"\n",
"Unfortunately, the model describes a four dimensional function, which makes it really hard to understand (and imagine, that there could easily be hundreds of input in a real model).\n",
"\n",
"One thing that we can do it look at the effect of two of the inputs at one time. For example, we can look at how inputs 0 and 1 change when we fix dimension 2 to 0.2 and dimension 3 to 0.9. The black line represents the decision boundary (where the model predicts a credit score of zero). If we are on the wrong side of this boundary, then our loan is refused."
],
"metadata": {
"id": "6LxuB6p3k-VM"
}
},
{
"cell_type": "code",
"source": [
"draw_2D_slice(model,0,1,0.2,0.9)"
],
"metadata": {
"id": "NblKr3W0dBJJ"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Similarly, we could look at how inputs 1 and 3 change the input when we set input 0 to 0.3 and input 2 to 0.2:"
],
"metadata": {
"id": "Fp2GeFn5mIRW"
}
},
{
"cell_type": "code",
"source": [
"draw_2D_slice(model,1,3,0.3,0.2)"
],
"metadata": {
"id": "VzIe0py5d5Bk"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"This tells us something -- it might be good for a reality check if we had some expectations about what effect each input would have, but it's still hard to ensure that the model does something sensible everywhere, especially for models where there are thousands of inputs. Unfortunately, there are basically no good solutions to this problem at the time of writing."
],
"metadata": {
"id": "A9XUV9B6m7v0"
}
},
{
"cell_type": "markdown",
"source": [
"However, let's view this from the perspective of a customer. We can assume that the four inputs have some particular values, and see what the output is."
],
"metadata": {
"id": "1w968kJQjjUm"
}
},
{
"cell_type": "code",
"source": [
"x = np.array([[0.3],[0.8],[0.6],[0.3]])\n",
"y = model.get_output(x)\n",
"print(\"Your credit score is %3.3f\"%(y))\n",
"print(\"Sorry, your loan is refused\")"
],
"metadata": {
"id": "Nr71IahkjfV3"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"Well, that is bad news. Why was our loan refused? We'd like to understand what we could do to improve our credit score. One way to do this is through individual conditional expectation or ICE plots ([Goldstein et al. 2015](https://arxiv.org/abs/1309.6392)). These take shows how the model output would change as we vary a single feature. Essentially, they answer the question: what if the $k^{th}$ feature had taken another value?"
],
"metadata": {
"id": "mafmi3dSkTuf"
}
},
{
"cell_type": "code",
"source": [
"def ice_plot(model, x, k):\n",
" # Get output for the input\n",
" y = model.get_output(x)\n",
"\n",
" # Possible values of the k'th dimension of the input\n",
" x_k_all = np.arange(0,1,0.001)\n",
" # TODO write code that varies the k'th dimension of x and runs the model on the result to create a series of outputs y\n",
" # Replace this line\n",
" y_all = np.zeros_like(x_k_all)\n",
"\n",
"\n",
"\n",
" fig, ax = plt.subplots()\n",
" ax.plot(x_k_all, np.squeeze(y_all), 'r-')\n",
" ax.plot(x[k],y,'ro') ;\n",
" ax.plot([0,1.0],[0.0,0.0],'k--')\n",
" ax.set_xlabel('Dimension x%d'%(k))\n",
" ax.set_ylabel('Credit score')\n",
" ax.set_xlim(0,1)\n",
" ax.set_ylim([-10,10])\n",
"\n",
" plt.show()\n",
"\n"
],
"metadata": {
"id": "v2nNsvW-m2fb"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "code",
"source": [
"ice_plot(model, x, 0)\n",
"ice_plot(model, x, 1)\n",
"ice_plot(model, x, 2)\n",
"ice_plot(model, x, 3)"
],
"metadata": {
"id": "5I91gzfSnL9N"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"We can learn something from this. For example, decreasing the value of $x_{3}$ would be the most effective way to increase our credit score. However, this might be impossible if it is a variable we can't control like our age. Perhaps decreasing $x_0$ and $x_{1}$ might improve it further. Well... perhaps, but we don't know what is going on in our model; it might also make things much worse.\n",
"\n",
"Local interpretable model-agnostic explanations or LIME ([Ribeiro et al. 2016](https://arxiv.org/abs/1602.04938)) approximate the main machine learning model locally around a given input using a simpler model that is easier to understand. \n",
"\n",
"The principle is simple. First, we sample some points $\\mathbf{x}_{i}$ close to the input $\\mathbf{x}$ that we are interested in. Then we find the outputs $\\mathbf{y}_i$ that correspond to those inputs. Now we have a training set, and we can train any other kind of model that explains this small area of the input space. This can be a model that is much more interpretable and easier to understand such as a linear model or a tree."
],
"metadata": {
"id": "RmjuAR7HojtR"
}
},
{
"cell_type": "code",
"source": [
"# TODO -- Choose 100 points where each element of x is perturbed by noise sampled from a uniform distribution\n",
"# that takes values between [-0.05 and 0.05]. Then run these points through the model.\n",
"# Replace these lines\n",
"x_lime_train = np.matlib.repmat(x, 1, 100)\n",
"y_lime_train = np.ones((1,100))\n",
"\n",
"# BEGIN_ANSWER\n",
"x_lime_train = x_lime_train + np.random.uniform(low=-0.05,high=0.05,size=x_lime_train.shape)\n",
"y_lime_train = model.get_output(x_lime_train)\n",
"# END_ANSWER"
],
"metadata": {
"id": "-GprSftsnS0M"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"We'll train a linear model:\n",
"\n",
"\\begin{equation}\n",
"y = \\beta_0 + \\boldsymbol\\phi^{T}\\mathbf{x}\n",
"\\end{equation}"
],
"metadata": {
"id": "yTFDYbqGqmcA"
}
},
{
"cell_type": "code",
"source": [
"# TODO -- train this model using a least squares loss\n",
"# to find values for the offset \\beta_0 and the four slopes in \\phi\n",
"# One way to do this is with sklearn.linear_model\n",
"# Replace this line\n",
"beta = 0; phi = np.zeros((1,4))\n",
"\n",
"print(phi)"
],
"metadata": {
"id": "5e4VPh40qlEl"
},
"execution_count": null,
"outputs": []
},
{
"cell_type": "markdown",
"source": [
"This model is easily interpretable. The k'th coefficient tells us the how much (and in which direction) changing the value of the k'th input will change the output. This is only valid in the vicinity of the input $x$.\n",
"\n",
"Note that a more sophisticated version of LIME would weight the training points according to how close they are to the original data point of interest."
],
"metadata": {
"id": "hsZHWuVWtzIK"
}
}
]
}

BIN
UDL_Answer_Booklet_Students.pdf
View File

Binary file not shown.

BIN
UDL_Errata.pdf Normal file
View File

Binary file not shown.

83
index.html
View File

@@ -11,15 +11,18 @@
<div>
<h1 style="margin: 0; font-size: 36px">Understanding Deep Learning</h1>
by Simon J.D. Prince
<br>To be published by MIT Press Dec 5th 2023.<br>
<br>Published by MIT Press Dec 5th 2023.<br>
<ul>
<li>
<p style="font-size: larger; margin-bottom: 0">Download draft PDF Chapters 1-21 <a
href="https://github.com/udlbook/udlbook/releases/download/v1.14/UnderstandingDeepLearning_13_10_23_C.pdf">here</a>
</p>2023-10-13. CC-BY-NC-ND license<br>
href="https://github.com/udlbook/udlbook/releases/download/v1.17/UnderstandingDeepLearning_17_12_23_C.pdf">here</a>
</p>2023-12-17. CC-BY-NC-ND license<br>
<img src="https://img.shields.io/github/downloads/udlbook/udlbook/total" alt="download stats shield">
</li>
<li> Report errata via <a href="https://github.com/udlbook/udlbook/issues">github</a>
<li> Order your copy from <a href="https://mitpress.mit.edu/9780262048644/understanding-deep-learning/">here </a></li>
<li> Known errata can be found here: <a
href="https://github.com/udlbook/udlbook/raw/main/UDL_Errata.pdf">PDF</a></li>
<li> Report new errata via <a href="https://github.com/udlbook/udlbook/issues">github</a>
or contact me directly at udlbookmail@gmail.com
<li> Follow me on <a href="https://twitter.com/SimonPrinceAI">Twitter</a> or <a
href="https://www.linkedin.com/in/simon-prince-615bb9165/">LinkedIn</a> for updates.
@@ -58,6 +61,7 @@
<h2>Resources for instructors </h2>
<p>Instructor answer booklet available with proof of credentials via <a
href="https://mitpress.mit.edu/9780262048644/understanding-deep-learning"> MIT Press</a>.</p>
<p>Request an exam/desk copy via <a href="https://mitpress.ublish.com/request?cri=15055">MIT Press</a>.</p>
<p>Figures in PDF (vector) / SVG (vector) / Powerpoint (images):
<ul>
<li> Chapter 1 - Introduction: <a href="https://github.com/udlbook/udlbook/raw/main/PDFFigures/UDLChap1PDF.zip">PDF
@@ -156,7 +160,7 @@
Figures</a>
<li> Chapter 16 - Normalizing flows: <a
href="https://github.com/udlbook/udlbook/raw/main/PDFFigures/UDLChap16PDF.zip">PDF Figures</a> / <a
href="https://drive.google.com/uc?export=download&id=1B9bxtmdugwtg-b7Y4AdQKAIEVWxjx8l3"> SVG Figures</a>
href="https://drive.google.com/uc?export=download&id=1B9bxtmdugwtg-b7Y4AdQKAIEVWxjx8l3"> SVG Figures</a>
/
<a href="https://docs.google.com/presentation/d/1nLLzqb9pdfF_h6i1HUDSyp7kSMIkSUUA/edit?usp=drive_link&ouid=110441678248547154185&rtpof=true&sd=true">PowerPoint
Figures</a>
@@ -168,7 +172,9 @@
Figures</a>
<li> Chapter 18 - Diffusion models: <a
href="https://github.com/udlbook/udlbook/raw/main/PDFFigures/UDLChap18PDF.zip">PDF Figures</a> / <a
href="https://docs.google.com/presentation/d/1x_ufIBtVPzWUvRieKMkpw5SdRjXWwdfR/edit?usp=drive_link&ouid=110441678248547154185&rtpof=true&sd=true">
href="https://drive.google.com/uc?export=download&id=1A-pIGl4PxjVMYOKAUG3aT4a8wD3G-q_r"> SVG Figures</a>
/
<a href="https://docs.google.com/presentation/d/1x_ufIBtVPzWUvRieKMkpw5SdRjXWwdfR/edit?usp=drive_link&ouid=110441678248547154185&rtpof=true&sd=true">
PowerPoint Figures</a>
<li> Chapter 19 - Deep reinforcement learning: <a
href="https://github.com/udlbook/udlbook/raw/main/PDFFigures/UDLChap19PDF.zip">PDF Figures</a> / <a
@@ -199,6 +205,23 @@
Instructions for editing figures / equations can be found <a
href="https://drive.google.com/file/d/1T_MXXVR4AfyMnlEFI-UVDh--FXI5deAp/view?usp=sharing">here</a>.
<p> My slides for 20 lecture undergraduate deep learning course:</p>
<ul>
<li><a href="https://drive.google.com/uc?export=download&id=17RHb11BrydOvxSFNbRIomE1QKLVI087m">1. Introduction</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1491zkHULC7gDfqlV6cqUxyVYXZ-de-Ub">2. Supervised Learning</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1XkP1c9EhOBowla1rT1nnsDGMf2rZvrt7">3. Shallow Neural Networks</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1e2ejfZbbfMKLBv0v-tvBWBdI8gO3SSS1">4. Deep Neural Networks</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1fxQ_a1Q3eFPZ4kPqKbak6_emJK-JfnRH">5. Loss Functions</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=17QQ5ZzXBtR_uCNCUU1gPRWWRUeZN9exW">6. Fitting Models</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1hC8JUCOaFWiw3KGn0rm7nW6mEq242QDK">7. Computing Gradients</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1tSjCeAVg0JCeBcPgDJDbi7Gg43Qkh9_d">7b. Initialization</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1RVZW3KjEs0vNSGx3B2fdizddlr6I0wLl">8. Performance</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1LTicIKPRPbZRkkg6qOr1DSuOB72axood">9. Regularization</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1bGVuwAwrofzZdfvj267elIzkYMIvYFj0">10. Convolutional Networks</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1Kllhj0HdS_I3qE2XDU6ifgGGj3tmSRcl">11. Image Generation</a></li>
<li><a href="https://drive.google.com/uc?export=download&id=1af6bTTjAbhDYfrDhboW7Fuv52Gk9ygKr">12. Transformers and LLMs</a></li>
</ul>
<h2>Resources for students</h2>
<p>Answers to selected questions: <a
@@ -342,29 +365,29 @@
<li> Notebook 13.4 - Graph attention: <a
href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap13/13_4_Graph_Attention_Networks.ipynb">ipynb/colab </a>
</li>
<li> Notebook 15.1 - GAN toy example: (coming soon)</li>
<li> Notebook 15.2 - Wasserstein distance: (coming soon)</li>
<li> Notebook 16.1 - 1D normalizing flows: (coming soon)</li>
<li> Notebook 16.2 - Autoregressive flows: (coming soon)</li>
<li> Notebook 16.3 - Contraction mappings: (coming soon)</li>
<li> Notebook 17.1 - Latent variable models: (coming soon)</li>
<li> Notebook 17.2 - Reparameterization trick: (coming soon)</li>
<li> Notebook 17.3 - Importance sampling: (coming soon)</li>
<li> Notebook 18.1 - Diffusion encoder: (coming soon)</li>
<li> Notebook 18.2 - 1D diffusion model: (coming soon)</li>
<li> Notebook 18.3 - Reparameterized model: (coming soon)</li>
<li> Notebook 18.4 - Families of diffusion models: (coming soon)</li>
<li> Notebook 19.1 - Markov decision processes: (coming soon)</li>
<li> Notebook 19.2 - Dynamic programming: (coming soon)</li>
<li> Notebook 19.3 - Monte-Carlo methods: (coming soon)</li>
<li> Notebook 19.4 - Temporal difference methods: (coming soon)</li>
<li> Notebook 19.5 - Control variates: (coming soon)</li>
<li> Notebook 20.1 - Random data: (coming soon)</li>
<li> Notebook 20.2 - Full-batch gradient descent: (coming soon)</li>
<li> Notebook 20.3 - Lottery tickets: (coming soon)</li>
<li> Notebook 20.4 - Adversarial attacks: (coming soon)</li>
<li> Notebook 21.1 - Bias mitigation: (coming soon)</li>
<li> Notebook 21.2 - Explainability: (coming soon)</li>
<li> Notebook 15.1 - GAN toy example: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap15/15_1_GAN_Toy_Example.ipynb">ipynb/colab </a></li>
<li> Notebook 15.2 - Wasserstein distance: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap15/15_2_Wasserstein_Distance.ipynb">ipynb/colab </a></li>
<li> Notebook 16.1 - 1D normalizing flows: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap16/16_1_1D_Normalizing_Flows.ipynb">ipynb/colab </a></li>
<li> Notebook 16.2 - Autoregressive flows: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap16/16_2_Autoregressive_Flows.ipynb">ipynb/colab </a></li>
<li> Notebook 16.3 - Contraction mappings: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap16/16_3_Contraction_Mappings.ipynb">ipynb/colab </a></li>
<li> Notebook 17.1 - Latent variable models: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap17/17_1_Latent_Variable_Models.ipynb">ipynb/colab </a></li>
<li> Notebook 17.2 - Reparameterization trick: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap17/17_2_Reparameterization_Trick.ipynb">ipynb/colab </a></li>
<li> Notebook 17.3 - Importance sampling: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap17/17_3_Importance_Sampling.ipynb">ipynb/colab </a></li>
<li> Notebook 18.1 - Diffusion encoder: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap18/18_1_Diffusion_Encoder.ipynb">ipynb/colab </a></li>
<li> Notebook 18.2 - 1D diffusion model: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap18/18_2_1D_Diffusion_Model.ipynb">ipynb/colab </a></li>
<li> Notebook 18.3 - Reparameterized model: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap18/18_3_Reparameterized_Model.ipynb">ipynb/colab </a></li>
<li> Notebook 18.4 - Families of diffusion models: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap18/18_4_Families_of_Diffusion_Models.ipynb">ipynb/colab </a></li>
<li> Notebook 19.1 - Markov decision processes: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap19/19_1_Markov_Decision_Processes.ipynb">ipynb/colab </a></li>
<li> Notebook 19.2 - Dynamic programming: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap19/19_2_Dynamic_Programming.ipynb">ipynb/colab </a></li>
<li> Notebook 19.3 - Monte-Carlo methods: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap19/19_3_Monte_Carlo_Methods.ipynb">ipynb/colab </a></li>
<li> Notebook 19.4 - Temporal difference methods: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap19/19_4_Temporal_Difference_Methods.ipynb">ipynb/colab </a></li>
<li> Notebook 19.5 - Control variates: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap19/19_5_Control_Variates.ipynb">ipynb/colab </a></li>
<li> Notebook 20.1 - Random data: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap20/20_1_Random_Data.ipynb">ipynb/colab </a></li>
<li> Notebook 20.2 - Full-batch gradient descent: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap20/20_2_Full_Batch_Gradient_Descent.ipynb">ipynb/colab </a></li>
<li> Notebook 20.3 - Lottery tickets: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap20/20_3_Lottery_Tickets.ipynb">ipynb/colab </a></li>
<li> Notebook 20.4 - Adversarial attacks: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap20/20_4_Adversarial_Attacks.ipynb">ipynb/colab </a></li>
<li> Notebook 21.1 - Bias mitigation: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap21/21_1_Bias_Mitigation.ipynb">ipynb/colab </a></li>
<li> Notebook 21.2 - Explainability: <a href="https://github.com/udlbook/udlbook/blob/main/Notebooks/Chap21/21_2_Explainability.ipynb">ipynb/colab </a></li>
</ul>
@@ -380,4 +403,4 @@
}
</code></pre>
</div>
</body>
</body>