Efficient FPGA implementation of homodyne-based time-of-flight range imaging

Autor:	Adrian P.P. Jongenelen, Adrian A. Dorrington, Andrew D. Payne, Donald G. Bailey, Dale A. Carnegie
Rok vydání:	2010
Předmět:	Pixel business.industry Computer science Real-time computing Computer graphics Range (mathematics) Stratix Computer vision Artificial intelligence Image sensor Field-programmable gate array business Chinese remainder theorem Information Systems Envelope (motion)
Zdroj:	Journal of Real-Time Image Processing. 7:21-29
ISSN:	1861-8219 1861-8200
DOI:	10.1007/s11554-010-0173-6
Popis:	Time-of-flight range imaging systems illuminate a scene with an amplitude-modulated light source, the light is reflected from objects in the scene, and measurement of the phase of the modulation envelope is performed to determine the object's distance. As the image sensor is capable of performing this task for every pixel simultaneously, acquisition of the entire scene can be performed at rapid (video) update rates, making the technology ideal for real-time applications. In this paper we present an efficient real-time FPGA algorithm for determining phase, and hence distance, from the raw image sensor output. The algorithm has been implemented on a range imaging system based on the PMD19k-2 image sensor, with range processing performed in real time by a Stratix III FPGA. The scarcest resource in this implementation is RAM, and an analysis is presented to maximise the efficiency of this resource whilst maintaining acceptable processing accuracy. The algorithm can be extended for processing multiple simultaneous modulation frequencies. An efficient method for combining these results to determine unambiguous range, based on the Chinese remainder theorem, is also presented.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::f74b4acd995a604ab03079531a9998df https://doi.org/10.1007/s11554-010-0173-6 Zobrazit plný text záznamu Full text from SpringerLink