Physical wavelets and radar: a variational approach to remote sensing

Author

Kaiser, Gerald

Author_Institution

Dept. of Math. Sci., Massachusetts Univ., Lowell, MA, USA

Volume

38

Issue

1

fYear

1996

fDate

2/1/1996 12:00:00 AM

Firstpage

15

Lastpage

24

Abstract

Physical wavelets are acoustic or electromagnetic waves, resulting from the emission of a time signal by a localized acoustic or electromagnetic source moving along an arbitrary trajectory in space. Thus, they are localized solutions of the wave equation or Maxwell´s equations. Under suitable conditions, such wavelets can be used as “basis” functions, to construct general acoustic or electromagnetic waves. This gives a local alternative to the construction of such waves in terms of (nonlocal) plane waves, via Fourier transforms. We give a brief, self-contained introduction to physical wavelets, and apply them to remote sensing. We define the ambiguity functional, generalization of the radar and sonar ambiguity functions, which applies not only to wideband signals, but also to targets and radar platforms executing arbitrary nonlinear motions

Keywords

radar signal processing; radar theory; radar tracking; remote sensing by radar; sonar signal processing; sonar tracking; variational techniques; wavelet transforms; Fourier transforms; Maxwell´s equation; acoustic waves; ambiguity functional generalization; ambiguity functions; basis functions; electromagnetic waves; nonlinear motions; physical wavelets; radar platforms; remote sensing; sonar; targets; variational approach; wave equation; wideband signals; Acoustic emission; Acoustic waves; Delay effects; Delay estimation; Electromagnetic scattering; Frequency estimation; Partial differential equations; Radar remote sensing; Remote sensing; Wideband;

fLanguage

English

Journal_Title

Antennas and Propagation Magazine, IEEE

Publisher

ieee

ISSN

1045-9243

Type

jour

DOI

10.1109/74.491287

Filename

491287