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Modern Computer Vision with PyTorch

You're reading from   Modern Computer Vision with PyTorch A practical roadmap from deep learning fundamentals to advanced applications and Generative AI

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Product type Paperback
Published in Jun 2024
Publisher Packt
ISBN-13 9781803231334
Length 746 pages
Edition 2nd Edition
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Authors (2):
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V Kishore Ayyadevara V Kishore Ayyadevara
Author Profile Icon V Kishore Ayyadevara
V Kishore Ayyadevara
Yeshwanth Reddy Yeshwanth Reddy
Author Profile Icon Yeshwanth Reddy
Yeshwanth Reddy
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Toc

Table of Contents (26) Chapters Close

Preface 1. Section 1: Fundamentals of Deep Learning for Computer Vision
2. Artificial Neural Network Fundamentals FREE CHAPTER 3. PyTorch Fundamentals 4. Building a Deep Neural Network with PyTorch 5. Section 2: Object Classification and Detection
6. Introducing Convolutional Neural Networks 7. Transfer Learning for Image Classification 8. Practical Aspects of Image Classification 9. Basics of Object Detection 10. Advanced Object Detection 11. Image Segmentation 12. Applications of Object Detection and Segmentation 13. Section 3: Image Manipulation
14. Autoencoders and Image Manipulation 15. Image Generation Using GANs 16. Advanced GANs to Manipulate Images 17. Section 4: Combining Computer Vision with Other Techniques
18. Combining Computer Vision and Reinforcement Learning 19. Combining Computer Vision and NLP Techniques 20. Foundation Models in Computer Vision 21. Applications of Stable Diffusion 22. Moving a Model to Production 23. Other Books You May Enjoy
24. Index
Appendix

Questions

  1. What is the “encoder” in an autoencoder?
  2. What loss function does an autoencoder optimize for?
  3. How do autoencoders help in grouping similar images?
  4. When is a convolutional autoencoder useful?
  5. Why do we get non-intuitive images if we randomly sample from the vector space of embeddings obtained from a vanilla/convolutional autoencoder?
  6. What are the loss functions that VAEs optimize for?
  7. How do VAEs overcome the limitation of vanilla/convolutional autoencoders to generate new images?
  8. During an adversarial attack, why do we modify the input image pixels and not the weight values?
  9. In a neural style transfer, what are the losses that we optimize for?
  10. Why do we consider the activation of different layers and not the original image when calculating style and content loss?
  11. Why do we consider the gram matrix loss and not the difference between images when calculating the style loss?
  12. Why do we warp...
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