Transformers in Vision: A Survey

Authors

Salman Khan, Mohamed bin Zayed University of Artificial Intelligence & Australian National UniversityFollow
Muzammal Naseer, Mohamed bin Zayed University of Artificial Intelligence & Australian National UniversityFollow
Munawar Hayat, Monash University
Syed Waqas Zamir, Inception Institute of Artificial IntelligenceFollow
Fahad Shahbaz Khan, Mohamed Bin Zayed University of Artificial Intelligence & Linköping UniversityFollow
Mubarak Shah, University of Central FloridaFollow

Document Type

Article

Publication Title

arXiv

Abstract

Astounding results from Transformer models on natural language tasks have intrigued the vision community to study their application to computer vision problems. Among their salient benefits, Transformers enable modeling long dependencies between input sequence elements and support parallel processing of sequence as compared to recurrent networks e.g., Long short-term memory (LSTM). Different from convolutional networks, Transformers require minimal inductive biases for their design and are naturally suited as set-functions. Furthermore, the straightforward design of Transformers allows processing multiple modalities (e.g., images, videos, text and speech) using similar processing blocks and demonstrates excellent scalability to very large capacity networks and huge datasets. These strengths have led to exciting progress on a number of vision tasks using Transformer networks. This survey aims to provide a comprehensive overview of the Transformer models in the computer vision discipline. We start with an introduction to fundamental concepts behind the success of Transformers i.e., self-attention, large-scale pre-training, and bidirectional feature encoding. We then cover extensive applications of transformers in vision including popular recognition tasks (e.g., image classification, object detection, action recognition, and segmentation), generative modeling, multi-modal tasks (e.g., visual-question answering, visual reasoning, and visual grounding), video processing (e.g., activity recognition, video forecasting), low-level vision (e.g., image super-resolution, image enhancement, and colorization) and 3D analysis (e.g., point cloud classification and segmentation). We compare the respective advantages and limitations of popular techniques both in terms of architectural design and their experimental value. Finally, we provide an analysis on open research directions and possible future works. We hope this effort will ignite further interest in the community to solve current challenges towards the application of transformer models in computer vision. © 2021, CC BY-SA.

DOI

doi.org/10.48550/arXiv.2101.01169v5

Publication Date

1-19-2022

Keywords

Computer vision, Convolution, Convolutional neural networks, Image enhancement, Image segmentation, Large dataset, Long short-term memory, Network coding, Object detection, Surveys, Three dimensional computer graphics, Video signal processing, Bidirectional encoder, Computer vision problems, Convolutional networks, Input sequence, Natural languages, Self-attention, Self-supervision, Transformer, Transformer modeling, Vision communities, Deep neural networks, Artificial Intelligence (cs.AI), Computer Vision and Pattern Recognition (cs.CV), Machine Learning (cs.LG)

Comments

Preprint: arXiv

Archived with thanks to arXiv

Preprint License: CC BY-SA 4.0

Uploaded 25 March 2022

Recommended Citation

S. Khan, M. Naseer, M. Hayat, S.W. Zamir, F.S. Khan, and M. Shah, "Transformers in vision: a survey", 2022, arXiv:2101.01169v5