Visual Inertial Odometry At the Edge: A Hardware-Software Co-design Approach for Ultra-low Latency and Power

Visual Inertial Odometry (VIO) is used for estimating pose and trajectory of a system and is a foundational requirement in many emerging applications like AR/VR, autonomous navigation in cars, drones and robots. In this paper, we analyze key compute bottlenecks in VIO and present a highly optimized...

Full description

Saved in:
Bibliographic Details
Published in2019 Design, Automation & Test in Europe Conference & Exhibition (DATE) pp. 960 - 963
Main Authors Mandal, Dipan Kumar, Jandhyala, Srivatsava, Omer, Om J, Kalsi, Gurpreet S, George, Biji, Neela, Gopi, Rethinagiri, Santhosh Kumar, Subramoney, Sreenivas, Hacking, Lance, Radford, Jim, Jones, Eagle, Kuttanna, Belliappa, Wang, Hong
Format Conference Proceeding
LanguageEnglish
Published EDAA 01.03.2019
Subjects
Acceleration
Feature detection
Feature extraction
Hardware
Pipelines
Throughput
Online AccessGet full text

Cover

More Information
Summary:Visual Inertial Odometry (VIO) is used for estimating pose and trajectory of a system and is a foundational requirement in many emerging applications like AR/VR, autonomous navigation in cars, drones and robots. In this paper, we analyze key compute bottlenecks in VIO and present a highly optimized VIO accelerator based on a hardware-software codesign approach. We detail a set of novel micro-architectural techniques that optimize compute, data movement, bandwidth and dynamic power to make it possible to deliver high quality of VIO at ultra-low latency and power required for budget constrained edge devices. By offloading the computation of the critical linear algebra algorithms from the CPU, the accelerator enables high sample rate IMU usage in VIO processing while acceleration of image processing pipe increases precision, robustness and reduces IMU induced drift in final pose estimate. The proposed accelerator requires a small silicon footprint (1.3 mm 2 in a 28nm process at 600 MHz), utilizes a modest on-chip shared SRAM (560KB) and achieves 10x speedup over a software-only implementation in terms of image sample-based pose update latency while consuming just 2.2 mW power. In a FPGA implementation, using the EuRoC VIO dataset (VGA 30fps images and 100Hz IMU) the accelerator design achieves pose estimation accuracy (loop closure error) comparable to a software based VIO implementation.
ISSN:1558-1101
DOI:10.23919/DATE.2019.8714921