Bistatic SAR/ISAR/FSR theory algorithms and program implementation
Bistatic radar consists of a radar system which comprises a transmitter and receiver which are separated by a distance comparable to the expected target distance. This book provides a general theoretical description of such bistatic technology in the context of synthetic aperture, inverse synthetic...
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
ISTE Ltd ; John Wiley & Sons :
London, England
2014.
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| Edición: | 1st edition |
| Colección: | Focus (National Council on Economic Education)
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| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009628099806719 |
Tabla de Contenidos:
- Cover; Title page; Contents; ACKNOWLEDGEMENT; CHAPTER 1. BISTATIC SYNTHETIC APERTURE RADAR (BSAR) SURVEY; 1.1. Introduction and main definitions; 1.2. Passive space-surface bistatic and multistatic SAR; 1.3. Forward scattering radars; 1.4. A moving target problem as an inversion problem in multistatic SAR; 1.5. BSAR models, imaging, methods and algorithms; 1.5.1. Range migration algorithm for invariant and variant flying geometry; 1.5.2. Bistatic point target reference spectrum based on Loffeld's bistatic formula; 1.5.3. Target parameters extraction; CHAPTER 2. BSAR GEOMETRY
- 2.1. BGISAR geometry and kinematics2.2. Multistatic BSAR geometry and kinematics; 2.3. BFISAR geometry and kinematics; 2.3.1. Kinematic parameter estimation; CHAPTER 3. BSAR WAVEFORMS AND SIGNAL MODELS; 3.1. Short pulse waveform and the BSAR signal model; 3.1.1. Short pulse waveform; 3.1.2. Short pulse BSAR signal model; 3.1.3. Target's parameters estimation in short range BFISAR scenario; 3.2. LFM pulse waveform; 3.2.1. LFM BSAR signal model; 3.3. CW LFM waveform and modeling of deterministic components of BSAR signal; 3.4. Phase code modulated pulse waveforms; 3.4.1. Barker phase code
- 3.4.2. Complementary code synthesis3.4.3. BSAR-transmitted complementary phase code modulated waveforms; 3.4.4. GPS C/A phase code; 3.4.5. GPS P phase code; 3.4.6. DVB-T waveform; CHAPTER 4. BSAR IMAGE RECONSTRUCTION ALGORITHMS; 4.1. Image reconstruction from a short pulse BSAR signal; 4.2. LFM BSAR image reconstruction algorithm; 4.3. PCM BSAR image reconstruction algorithm; 4.4. Autofocus algorithm with entropy minimization; 4.5. Experiment with the multistatic SAR LFM image reconstruction algorithm; CHAPTER 5. ANALYTICAL GEOMETRICAL DETERMINATION OF BSAR RESOLUTION
- 5.1. Generalized BSAR range and Doppler resolution5.1.1. BSAR range resolution; 5.1.2. BSAR Doppler resolution; 5.2. Along-track range resolution; 5.3. Range resolution along a target-receiver line of sight; CHAPTER 6. BSAR EXPERIMENTAL RESULTS; 6.1. Example 1: BFISAR with short-pulse waveform; 6.1.1. BFISAR parameters estimation; 6.1.2. BFISAR signal formation algorithm; 6.2. Example 2: BFISAR with pulse LFM waveform; 6.2.1. BFISAR geometry and isorange ellipse parameter estimation; 6.2.2. BFISAR LFM signal formation algorithm; 6.2.3. Image reconstruction algorithm and experimental results
- 6.3. Example 3: asymmetric geometry of BFISAR with pulse LFM waveform6.3.1. BFISAR LFM signal formation algorithm; 6.3.2. BFISAR image reconstruction algorithm and experimental results; 6.4. Example 4: BGISAR with Barker PCM waveform; 6.4.1. BGISAR Barker PCM signal formation algorithm; 6.4.2. BGISAR image reconstruction algorithm and experimental results; 6.5. Example 5: BGISAR with GPS C/A PCM waveform; 6.5.1. BGISAR GPS C/A PCM signal formation algorithm; 6.5.2. BGISAR image reconstruction algorithm and experimental results; 6.6. Example 6: BGISAR with GPS P PCM waveform
- 6.6.1. BGISAR GPS P PCM signal formation algorithm
