Estimating Power, Performance, and Area for On-Sensor Deployment of AR/VR Workloads Using an Analytical Framework
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Published:2024-06-07
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ISSN:1084-4309
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Container-title:ACM Transactions on Design Automation of Electronic Systems
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language:en
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Short-container-title:ACM Trans. Des. Autom. Electron. Syst.
Author:
Sun Xiaoyu1, Peng Xiaochen1, Zhang Sai2, Gomez Jorge2, Khwa Win-San3, Sarwar Syed2, Li Ziyun2, Cao Weidong4, Wang Zhao2, Liu Chiao2, Chang Meng-Fan3, Salvo Barbara2, Akarvardar Kerem1, Wong H.-S. Philip5
Affiliation:
1. Taiwan Semiconductor Manufacturing Company North America, San Jose, United States 2. Meta Reality Labs, Redmond, United States 3. Taiwan Semiconductor Manufacturing Co Ltd, Hsinchu, Taiwan 4. The George Washington University, Washington, United States 5. Taiwan Semiconductor Manufacturing Company, USA
Abstract
Augmented Reality and Virtual Reality have emerged as the next frontier of intelligent image sensors and computer systems. In these systems, 3D die stacking stands out as a compelling solution, enabling in-situ processing capability of the sensory data for tasks such as image classification and object detection at low power, low latency, and a small form factor. These intelligent 3D CMOS Image Sensor (CIS) systems present a wide design space, encompassing multiple domains (e.g., computer vision algorithms, circuit design, system architecture, and semiconductor technology, including 3D stacking) that have not been explored in-depth so far. This paper aims to fill this gap. We first present an analytical evaluation framework, STAR-3DSim, dedicated to rapid pre-RTL evaluation of 3D-CIS systems capturing the entire stack from the pixel layer to the on-sensor processor layer. With STAR-3DSim, we then propose several knobs for PPA (power, performance, area) improvement of the Deep Neural Network (DNN) accelerator that can provide up to 53%, 41%, and 63% reduction in energy, latency, and area, respectively, across a broad set of relevant AR/VR workloads. Lastly, we present full-system evaluation results by taking image sensing, cross-tier data transfer, and off-sensor communication into consideration.
Publisher
Association for Computing Machinery (ACM)
Reference59 articles.
1. M. Abrash, "Creating the future: Augmented reality, the next human-machine interface," in 2021 IEEE International Electron Devices Meeting (IEDM), 2021. 2. A 3.0 Gsymbol/s/lane MIPI C-PHY Receiver with Adaptive Level-Dependent Equalizer for Mobile CMOS Image Sensor;Choi S.;Sensors,2021 3. C. Liu, S. Chen, T.-H. Tsai, B. D. Salvo and J. Gomez, "Augmented Reality-The Next Frontier of Image Sensors and Compute Systems," in 2022 IEEE International Solid-State Circuits Conference (ISSCC), 2022. 4. J. Gomez, S. Patel, S. S. Sarwar, Z. Li, R. Capoccia, Z. Wang, R. Pinkham, A. Berkovich, T.-H. Tsai, B. D. Salvo and C. Liu, "Distributed on-sensor compute system for AR/VR devices: A semi-analytical simulation framework for power estimation," arXiv preprint arXiv:2203.07474, 2022. 5. 3-D stacked image sensor with deep neural network computation;Amir M. F.;IEEE Sensors Journal,2018
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