Design of Multi-frequency CW Radars
Author: Mohinder Jankiraman
Product Code: SBRA0040
Stock Status: In stock
£70.85 Member price
£109.00 Full price
This book deals with the basic theory for design and analysis of Low Probability of Intercept (LPI) radar systems. The design of one such multi-frequency high resolution LPI radar, PANDORA, is covered. This work represents the first time that the topic of multi-frequency radars is discussed in such detail and it is based on research conducted by the author in The Netherlands. The book provides the design tools needed for development, design, and analysis of high resolution radar systems for commercial as well as military applications. Software written in MATLAB and C++ is provided to guide the reader in calculating radar parameters and in ambiguity function analysis. Some radar simulation software is also included.
Supplementary material files can be found on IET Digital Library.
"Design of Multi-Frequency Radars is an excellent and modern contribution to FMCW radar technology. It not only introduces current FMCW theory but also provides design details and performance of several recent FMCW radars. This will help any system analyst, radar/EW system designer or hardware engineer with their own designs as well as assessing the designs of others. Most importantly the book shows hardware signal level calculations including phase noise estimates and measurements, self noise considerations and estimated dynamic range. Many easy to follow detailed design considerations not normally found in textbooks are provided, which will be of great help to anyone in the field."
- prepublication review by David Lynch, Jr., DL Sciences Inc.
Part I: Fundamentals of CW Radar
1. Frequency Modulated Continuous Wave (FMCW) Radar
2. Radar Waveforms and Processing
3. The Radar Ambiguity Function
4. FMCW Waveform
5. Phase-Coded Waveform
6. Frequency Hopped Waveform
Part II: Theory and Design of Calypso FMCW Radar
7. Design Approach
Part III: Theory and Design of Pandora Multifrequency Radar
8. Design Approach
9. Implementation of the Single Channel Pandora and Other Issues
10. PANDORA Multi-channel Radar
A CW Radar Range Equations
B The Design Process
C A Hardware Solution to the Range Resolution Problem
D Non-Linearity in FM Waveforms
E Transmitter Noise Leakage
F Pandora Receiver Channel-Basic Design
G Direct Digital Synthesis
H Implementation of the Single Channel Radar
I Pandora Radar Performance Verification Measurements
J 8 Way Combiner Analysis Results
K MATLAB Simulation Program
L Level Diagram Calculations -- SFCW Radar
List of Symbols
Description of Software
About the author
Dr. Mohinder Jankiraman received his B. Tech. degree in electronics and telecommunications from the Naval Electrical School in Jamnagar, India, in 1971. Subsequently, he served as an electrical officer in the Indian Navy for many years. In 1982 he was seconded to research work in military electronics. He took part in a number of military research projects and won a number of awards for technology development in India. His research has spanned several disciplines, emphasizing signal processing, development of naval mines, torpedoes, sonars, radar, and communication systems. He retired from the Indian Navy in 1995 with the rank of a Commodore and joined the International Research Centre for Telecommunications and Radar (IRCTR) in the Delft University of Technology, Netherlands, in 1997. During this period, he took part in the research and development program for high-resolution radars at IRCTR.
Dr. Jankiraman completed his Master of Technology in Design (MTD) degree in 1999, from Delft University of Technology, The Netherlands, graduating cum laude, and went on to complete his Ph.D. from Aalborg University, Denmark, in September 2000. He is currently living in the United States, based in Dallas, Texas. He is a senior member of IEEE.