Download Processor MODEX-1

RADARSAT-2 MOVING OBJECT DETECTION EXPERIMENT (MODEX)
Shen Chiu, Chuck Livingstone, Ishuwa Sikaneta, Christoph Gierull, and Pete Beaulne
Defence R&D Canada, Radar Systems Section
3701 Carling Avenue, Ottawa, Ontario, Canada K1A 0Z4
1. INTRODUCTION
Canada’s next-generation commercial radar satellite RADARSAT-2 was successfully launched on December 14, 2007 [1].
RADARSAT-2 MODEX is a scientific project aimed at developing, validating, and demonstrating an experimental space-based
ground moving target indication (GMTI) mode to routinely detect, measure, and monitor vehicles moving on the Earth’s surface
[2]. MODEX has been implemented through collaboration between DND, the Canadian Space Agency, and the satellite builder,
MDA Corporation, Ltd. The RADARSAT-2 SAR antenna can be partitioned into two sub-apertures aligned along the direction
of flight, thus permitting successive scene observations. Comparison of the observations reveals objects that have moved or
changed in the intervening time.
2. MODEX PROCESSORS
Several moving target detection and estimation algorithms have been implemented for the planned MODEX. Among the detectors implemented are Displaced Phase Center Antenna (DPCA) [3], Histogram Along-Track Interferometry (HATI) [4],
and Hyperbolic Detector [3]. The estimators that were implemented include Matched-Filter Bank (MFB) [5], Along-Track
Interferometry (ATI) [5], and Fractrum Estimator [6] (see Fig. 1).
Processor MODEX-1
Pre-process
SAR
Process
De-crypt
• Detectors Classical • Detectors DRDC
– DPCA
– Hyperbolic
– ATI phase
– HATI
Arbitrate detections
• Estimator target
parameters
Arbitrate estimates
– ATI phase
– Matched filter bank
– Fractrum
Defence R&D Canada
Format data
e.g. (4607)
R et D pour la défense Canada
Fig. 1. RADARSAT-2 MODEX-1 processor architecture
The MODEX processor development through contract with MDA was completed in May 2007. In this contract, MDA created the worlds first satellite-based CFAR GMTI detector and estimator using algorithms developed at Defence R&D Canada
(DRDC) – Ottawa . Due to budget and time constraints, MDA only implemented what we call a MODEX-1 processor, which
includes a pre-processor to prepare the data for GMTI processing as well as two-antenna techniques to detect and estimate moving target parameters. The processor upgrade (or MODEX-2) is currently underway to implement toggle mode data processing
and waveform diversity processing as well as three-antenna detectors and estimation methods (e.g. STAP).
3. POST LAUNCH TRIALS
Due to RADARSAT-2’s orbit coverage and revisit rates, MODEX is not expected to provide significant operational military
capability in its current incarnation. Rather, it is primarily intended to assess the potential of space-based GMTI and to provide
information and recommendations for the conception and design of future operational space based GMTI systems. As such, a
series of post launch tests and experiments will be necessary to explore the performance of the entire RARARSAT-2 GMTI system. The aim of the post launch trials will be to investigate, in differing clutter environments, the most promising configurations
of the R2-GMTI system for military use.
4. PURPOSE OF THE PAPER
This paper will present an overview of various detection and estimation algorithms that have been implemented for the planned
MODEX as well as experimental plans for the validation and demonstration of the space-based GMTI mode. Preliminary
RADARSAT-2 GMTI results will also be presented.
5. REFERENCES
[1] “Radarsat-2 successfully launched,” http://www.radarsat2.info/outreach/innews/outreach/innews/2007/12142007 gsi.asp,
December 2007.
[2] C.E. Livingstone and A.A. Thompson, “The moving object detection experiment on RADARSAT-2,” Can. J. Remote
Sensing, vol. 30, no. 3, pp. 355–368, June 2004.
[3] I. C. Sikaneta and J.-Y. Chouinard, “Eigendecomposition of the multi-channel covariance matrix with applications to
SAR-GMTI,” Signal Processing, vol. 84, no. 9, pp. 1501–1535, September 2004.
[4] S. Chiu, “A constant false alarm rate (CFAR) detector for RADARSAT-2 along-track interferometry,” Can. J. Remote
Sensing, vol. 31, no. 1, pp. 73–84, February 2005.
[5] C.H. Gierull, “Ground moving target parameter estimation for two-channel SAR,” Radar, Sonar and Navigation, IEE
Proceedings, vol. 153, no. 3, pp. 224–233, June 2006.
[6] S. Chiu, “Application of fractional Fourier transform to moving target indication via along-track interferometry,” EURASIP
Journal on Applied Signal Processing, vol. 2005, no. 20, pp. 3293–3303, 2005.