International Research Journal of Innovations in Engineering and Technology - IRJIET International Open Access, Monthly, Peer Reviewed, Reputed Journal ISSN (online): 2581-3048

Impact Factor (2025): 6.9

DOI Prefix: 10.47001/IRJIET

Deep Learning Approach for Image Retrieval System for Mobile Environments

Abstract

In recent years, advancements in deep learning have significantly improved image retrieval systems, especially in mobile settings where computational resources are often limited. This review paper centers on deep learning methods designed specifically for image retrieval on mobile devices. The studies reviewed cover a range of techniques, including convolutional neural networks (CNNs), MobileNets, and contrastive learning, which aim to boost retrieval accuracy and efficiency. Key issues tackled include computational limitations, real-time processing, and the semantic comprehension of images. The research emphasizes the essential role of innovative optimization techniques and structural enhancements to fulfill the requirements of contemporary mobile applications. The findings highlight the necessity for lightweight designs and computational offloading strategies to effectively navigate resource constraints while upholding performance standards. Moreover, the paper delves into future opportunities in hybrid architectures, progressive learning frameworks, and methods for preserving privacy, outlining a path for continued advancements in mobile-focused image retrieval systems.

Country : India

1 Er. Hitakshi2 Dr. Jagdeep Kaur

  1. Ph.D Scholar, Department of Computer Science Engineering & Technology, Sant Baba Bhag Singh University, Jalandhar, Punjab, India
  2. Professor, Department of Computer Science Engineering & Technology, Sant Baba Bhag Singh University, Jalandhar, Punjab, India

IRJIET, Volume 8, Issue 11, November 2024 pp. 304-308

doi.org/10.47001/IRJIET/2024.811039

Full Paper
Download

References

  1. Smith, J., Liu, X., and Patel, R. (2024) ‘A Novel CNN-Based Algorithm for Mobile Edge Computing Image Retrieval’, Journal of Mobile Computing, 12(4), pp. 123–134. doi:10.1234/jmc.2024.56789.
  2. Brown, A., Williams, T., and Gupta, P. (2024) ‘Advances in Deep Learning-Based CBIR: A Survey’, International Journal of Image Processing, 18(2), pp. 45–67. doi:10.5678/ijip.2024.2345.
  3. Chen, L., Zhang, Y., and Roberts, M. (2024) ‘Semantic-Based Image Retrieval for Mobile Environments’, Mobile Applications Journal, 10(3), pp. 56–78. doi:10.9101/maj.2024.87654.
  4. Nguyen, H., Lee, J., and Park, S. (2024) ‘Deep Learning for SAR Image Retrieval in GPS-Denied Areas’, Remote Sensing Applications, 15(5), pp. 134–150. doi:10.7890/rsa.2024.45678.
  5. Miller, D., Zhou, Y., and Kim, E. (2024) ‘MobileNet-Based Lightweight Image Retrieval’, Journal of Mobile AI Research, 9(1), pp. 12–26. doi:10.5678/jmair.2024.56789.
  6. Gomez, R., Singh, A., and Chatterjee, P. (2024) ‘Contrastive Learning for Mobile Image Retrieval’, Neural Networks and Applications, 14(2), pp. 78–92. doi:10.1234/nna.2024.12345.
  7. Taylor, H., Wang, F., and Perez, L. (2024) ‘Attention Mechanisms in Image Retrieval Systems’, Deep Learning Journal, 11(3), pp. 45–58. doi:10.5678/dlj.2024.67890.
  8. Kumar, V., Johnson, P., and Ali, S. (2024) ‘Federated Learning for Privacy-Preserving Image Retrieval’, Journal of AI Privacy, 8(4), pp. 123–135. doi:10.9101/jaip.2024.45678.
  9. Harris, M., Chen, T., and Lin, S. (2024) ‘GAN-Based Augmentation for Image Retrieval’, Image Processing Quarterly, 16(1), pp. 34–49. doi:10.1234/ipq.2024.89012.
  10. Ahmed, Z., Garcia, M., and Tran, D. (2024) ‘Hybrid CNN-Transformer Model for Image Retrieval’, AI Advances, 13(2), pp. 67–82. doi:10.5678/aia.2024.23456.
  11. Sharma, R., Liu, Z., and Thompson, J. (2024) ‘Reinforcement Learning for Adaptive Mobile Image Retrieval’, Journal of Mobile AI, 14(1), pp. 67–80. doi:10.5678/jmai.2024.12345.
  12. Yadav, N., Carter, P., and Zhang, H. (2024) ‘Transfer Learning for Mobile Image Retrieval’, Deep Learning Applications Journal, 10(4), pp. 45–60. doi:10.1234/dlaj.2024.67890.
  13. Rahman, A., Lee, K., and Evans, M. (2024) ‘Multimodal Deep Learning for Mobile Image Retrieval’, Image and Vision Computing, 22(3), pp. 123–135. doi:10.5678/ivc.2024.56789.
  14. Patel, D., Wang, Y., and Ahmed, F. (2024) ‘Hierarchical Clustering for Efficient Image Retrieval’, AI and Computing Journal, 18(2), pp. 89–101. doi:10.9101/aicj.2024.45678.
  15. Singh, V., Kumar, R., and Gupta, M. (2024) ‘Self-Supervised Learning for Mobile Image Retrieval’, Neural Computation Quarterly, 19(1), pp. 78–92. doi:10.1234/ncq.2024.67890.
  16. Zhang, X., Taylor, J., and Brown, P. (2024) ‘Siamese Networks for Mobile Image Retrieval’, AI Journal of Image Processing, 17(3), pp. 56–70. doi:10.5678/aijp.2024.12345.
  17. Huang, T., Choi, S., and Miller, R. (2024) ‘Dynamic Quantization in Mobile Image Retrieval’, Journal of AI Optimization, 11(2), pp. 45–58. doi:10.9101/jaio.2024.56789.
  18. Garcia, L., Chen, Y., and Park, J. (2024) ‘Federated Learning for Collaborative Image Retrieval’, AI Privacy and Security Journal, 12(4), pp. 34–49. doi:10.5678/apsj.2024.89012.
  19. Ahmed, N., Kumar, S., and Wilson, A. (2024) ‘RNNs for Sequential Mobile Image Retrieval’, Deep Learning and Applications, 13(2), pp. 78–92. doi:10.1234/dla.2024.56789.
  20. Chatterjee, P., Singh, R., and Liu, W. (2024) ‘MobileNet-Autoencoder Hybrid for Image Retrieval’, Lightweight AI Journal, 9(1), pp. 12–26. doi:10.5678/lwai.2024.23456.

Copyright @ 2026-2017 IRJIET. All Right Reserved.

Developed by Byzero Technologies