David G. Long
Brigham Young University
388 Papers
2.2K Citations
David G. Long is an academic researcher from Brigham Young University. The author has contributed to research in topics: Scatterometer & Sea ice. The author has an hindex of 42, co-authored 381 publications. Previous affiliations of David G. Long include California Institute of Technology & University of Southern California.
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Papers
•Book
Microwave Radar and Radiometric Remote Sensing
Fawwaz T. Ulaby,David G. Long,William J. Blackwell,Charles Elachi,Adrian K. Fung,Christopher S. Ruf,Kamal Sarabandi,Howard A. Zebker,Jakob van Zyl +8 more
- 04 Nov 2013
TL;DR: This comprehensive and up-to-date resource provides you with theoretical models, system design and operation, and geoscientific applications of active and passive microwave remote sensing systems.
1.3K
Array signal processing
TL;DR: This book is very referred for you because it gives not only the experience but also lesson, that's not about who are reading this array signal processing book but about this book that will give wellness for all people from many societies.
733
Spaceborne radar measurement of wind velocity over the ocean-an overview of the NSCAT scatterometer system
F.M. Naderi,Michael H. Freilich,David G. Long +2 more
- 01 Jun 1991
TL;DR: The NSCAT system includes several enhancements, such as three antenna azimuths in each of two swaths, and an onboard digital Doppler processor to allow backscatter measurements to be colocated everywhere within the orbit as mentioned in this paper.
Image reconstruction and enhanced resolution imaging from irregular samples
D.S. Early,David G. Long +1 more
TL;DR: This paper discusses a general theory and techniques for image reconstruction and creating enhanced resolution images from irregularly sampled data, and shows that with minor modification, the algebraic reconstruction technique (ART) is functionally equivalent to Grochenig's irregular sampling reconstruction algorithm.
Resolution enhancement of spaceborne scatterometer data
TL;DR: A method for generating enhanced resolution radar images of the Earth's surface using spaceborne scatterometry using an image reconstruction technique that takes advantage of the spatial overlap in scatterometer measurements made at different times to provide enhanced imaging resolution is presented.