Generative Adversarial Networks for Anime Character Generation

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15. #denatechcon AGENDA

16. #denatechcon (@hamadakoichi) Mobage 2010 6 Mobage2011 4 DeNA DeNA2014 10 : ( ) TokyoWebmining - 1500 - 2010 60 DeNA 8 AI AI AI

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21. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCV Workshop 2018. (ECCV: European Conference on Computer Vision)

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25. #denatechcon 1 3 5 7 2 4 6 8

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27. #denatechcon ProgressiveGAN (Karras et al., ICLR 2018) BigGAN (Brock et al., ICLR 2019) 1 3 5 7 2 4 6 8

28. #denatechcon ProgressiveGAN (Karras et al., ICLR 2018) BigGAN (Brock et al., ICLR 2019)

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32. #denatechcon Generative Adversarial Nets. Ian J. Goodfellow, Jean Pouget-Abadie, Mehdi Mirza, Bing Xu, David Warde- Farley, Sherjil Ozair, Aaron Courville, Yoshua Bengio. arXiv:1406.2661. In NIPS 2014.

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36. #denatechcon Progressive Growing of GANs for Improved Quality, Stability, and Variation. Tero Karras, Timo Aila, Samuli Laine, Jaakko Lehtinen. In ICLR 2018. (1024X1024) (256x256)

37. #denatechcon .441 7 545 7 4 / Progressive Growing of GANs for Improved Quality, Stability, and Variation Tero Karras, Timo Aila, Samuli Laine, Jaakko Lehtinen. In ICLR 2018.

38. #denatechcon / 5. 44 5 Progressive Growing of GANs for Improved Quality, Stability, and Variation Tero Karras, Timo Aila, Samuli Laine, Jaakko Lehtinen. In ICLR 2018.

41. #denatechcon + Spectral Normalization on Generator + Self Attention + Two Time Scale Update Rule (512x512) + Spectral Normalization on Discriminator + Projection Discriminator SNGAN with Projection (Miyato+, ICLR’18) SAGAN (Zhang+, 18) BigGAN (Brock+, ICLR’19) + Large Batch Size (256→2048) + Large Channel (64→96) + Shared Embedding + Hierarchical Latent Space + Truncation Trick + Orthogonal Regularization + First Singular Value Clamp + Zero-centered Gradient Penalty Large Scale GAN Training for High Fidelity Natural Image Synthesis. Andrew Brock, Jeff Donahue, Karen Simonyan. arXiv:1809.11096. In ICLR 2018.

42. #denatechcon (512x512) Generator Typical Architecture Res Block Architecture for ImageNet at 512x512 Large Scale GAN Training for High Fidelity Natural Image Synthesis. Andrew Brock, Jeff Donahue, Karen Simonyan. arXiv:1809.11096. In ICLR 2019.

43. #denatechcon (512x512) Large Scale GAN Training for High Fidelity Natural Image Synthesis. Andrew Brock, Jeff Donahue, Karen Simonyan. arXiv:1809.11096. In ICLR 2019.

44. #denatechcon Large Scale GAN Training for High Fidelity Natural Image Synthesis. Andrew Brock, Jeff Donahue, Karen Simonyan. arXiv:1809.11096. In ICLR 2019. (512x512)

54. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. 00./ 0

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71. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. 0 0 0 0 0 0 0 0 0 0 0

72. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018.

74. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. 0 0 0 0 0 0 0 0 0 0 0

80. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. 00./ 0 Full-body anime generation at 1024x1024 with Progressive Structure-conditional GANs

82. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. // . 0/0 Adding action to full-body anime characters with Progressive Structure-conditional GANs

84. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. (ICLR’18)

85. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. (ICLR’18)

86. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. (ICLR’18) (NIPS’17) (NIPS’17)

87. #denatechcon Full-body High-resolution Anime Generation with Progressive Structure-conditional Generative Adversarial Networks Koichi Hamada, Kentaro Tachibana, Tianqi Li, Hiroto Honda, and Yusuke Uchida. In ECCVW 2018. (ICLR’18) (NIPS’17) (NIPS’17)

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114. #denatechcon 8 1 1 1 Super SloMo: High Quality Estimation of Multiple Intermediate Frames for Video Interpolation. Huaizu Jiang, Deqing Sun, Varun Jampani, Ming-Hsuan Yang, Erik Learned-Miller, Jan Kautz. In CVPR 2018.

115. #denatechcon /30 480 6 2/81 4C + 60 2 • 8 , Super SloMo: High Quality Estimation of Multiple Intermediate Frames for Video Interpolation. Huaizu Jiang, Deqing Sun, Varun Jampani, Ming-Hsuan Yang, Erik Learned-Miller, Jan Kautz. In CVPR 2018. https://youtu.be/MjViy6kyiqs Research at NVIDIA: Transforming Standard Video Into Slow Motion with AI

116. #denatechcon 7 1 Video Frame Synthesis using Deep Voxel Flow. Ziwei Liu, Raymond A. Yeh, Xiaoou Tang, Yiming Liu, Aseem Agarwala. In ICCV 2017.

117. #denatechcon N I 7 B7 =: B = P 77 = 7: :=D • /0 (+ /0 , Video Frame Synthesis using Deep Voxel Flow. Ziwei Liu, Raymond A. Yeh, Xiaoou Tang, Yiming Liu, Aseem Agarwala. In ICCV 2017. BB F=CBC 67 ?. / 3: 1 B Video Frame Synthesis using Deep Voxel Flow

118. #denatechcon D F 6 + 23C • 1 76 , P SV P J IOM S R • ( ,24 c SV P J ,24 cP / ++ C • 1 76 , P J SV P • 4 8 4 0 L a Super SloMo(Adobe) Super SloMo Deep Voxel Flow Video Frame Synthesis using Deep Voxel Flow. Ziwei Liu, Raymond A. Yeh, Xiaoou Tang, Yiming Liu, Aseem Agarwala. In ICCV 2017. Super SloMo: High Quality Estimation of Multiple Intermediate Frames for Video Interpolation. Huaizu Jiang, Deqing Sun, Varun Jampani, Ming-Hsuan Yang, Erik Learned-Miller, Jan Kautz. In CVPR 2018. F

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130. #denatechcon G I0 I4 Optical Flow I1, I2, I3 (Generated)

131. #denatechcon G I0 I4 D Optical Flow I1, I2, I3 (Generated) Ground Truth

132. #denatechcon G I0 I4 D Optical Flow I1, I2, I3 (Generated) Ground Truth MSE

133. #denatechcon G I0 I4 D Optical Flow Ground Truth I1, I2, I3 (Generated) Ground Truth Generated MSE MSE

134. #denatechcon G I0 I4 D Optical Flow Ground Truth I1, I2, I3 (Generated) Ground Truth Generated MSE MSE

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136. #denatechcon Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU Local Discriminator “Real” or “Fake” Local Patch (16×16pix)

137. #denatechcon Conv-BN-ReLU Conv-BN-ReLU Generated Image Sequense Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU Conv-BN-ReLU FC Local Discriminator Temporal Discriminator “Real” or “Fake” Local Patch (16×16pix) Image Sequense “Real” or “Fake”

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139. #denatechcon Video

140. #denatechcon image0 image1 image2 image3 image4Video

141. #denatechcon ⁃ step size = 4 7FPS -> 30FPS 001.png, 005.png, 009.png, 013.png, 017.png ⁃ step size = 1 30FPS -> 120FPS 001.png, 002.png, 003.png, 004.png, 005.png

142. #denatechcon ⁃ step size = 4 7FPS -> 30FPS 001.png, 005.png, 009.png, 013.png, 017.png ⁃ step size = 1 30FPS -> 120FPS 001.png, 002.png, 003.png, 004.png, 005.png

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144. #denatechcon Frame Frame Deep Voxel FlowInput // . / Experimental Results: “Anime Frame Generation with Structure-consistent Prediction GANs”

145. #denatechcon step size = 1 step size = 4 step size = 7 step size = 10 Input SPGAN (Ours) Deep Voxel Flow 4 // . / Experimental Results: “Anime Frame Generation with Structure-consistent Prediction GANs”

146. #denatechcon Deep Voxel Flow Ours 1.average PSNR/SSIM on test dataset step size=4 PSNR SSIM Deep Voxel Flow 23.32 0.9294 SPGAN(Ours) 24.27 0.9407

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159. #denatechcon TZ ... ./ 0 KD SL KA N O N KD SL K N W (3 Frame) AI (x16 ) Input Frames Generated Frames 78 : : 102*0DeNA AI :

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Generative Adversarial Networks for Anime Character Generation

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Generative Adversarial Networks for Anime Character Generation