Techniques for spaceborne remote sensing of earth’s oceans using reflected GNSS signals

Global Navigation Satellite System (GNSS) Reflectometry (GNSS-R) is a low mass, power, volume and ultimately cost remote sensing technology that has recently been demonstrated on spaceborne platforms. However, GNSS-R is still relatively immature compared to other remote sensing technologies and ther...

Full description

Bibliographic Details
Main Author: Southwell, Benjamin
Format: Doctoral or Postdoctoral Thesis
Language:unknown
Published: UNSW Sydney 2019
Subjects:
Bistatic radar
GNSS-R
Reflectometry
Specular point
Adaptive filtering
Remote sensing
GPS-R
Doppler effect
Delays
Receivers
Wind
Wind direction
Delay doppler map
DDM
Range walk compensation
Simulator
Monostatic point
Backscattering
Ambiguous stare processing
Ambiguity resolution
Blind clutter suppression
Predecetion
Track before detect
Range migration
Doppler walk
Satellite applications
Moving target indicator
Decovolution
Incoherent integration
Practical receiver design
Osculating sphere
Minimum path length
Forward scattering
Woodward's ambiguity Function
Matched filter
Target detection
Sea ice
Attitude estimation
Adaptive window
Stare processing
Ice Sheet
Online Access:https://dx.doi.org/10.26190/unsworks/21555
http://hdl.handle.net/1959.4/64758
Description
Summary:Global Navigation Satellite System (GNSS) Reflectometry (GNSS-R) is a low mass, power, volume and ultimately cost remote sensing technology that has recently been demonstrated on spaceborne platforms. However, GNSS-R is still relatively immature compared to other remote sensing technologies and there remains significant work to be done before its capabilities are fully realised. In this thesis, techniques to produce and process Delay Doppler Maps (DDM)s using spaceborne receivers with a focus on ocean applications are developed. A new approach to determine the forward scattered specular point is developed which improves the positioning accuracy by over 20 km compared to the current state-of-the-art. This is followed by the investigation of the pseudo monostatic point and a statistical analysis of the two. The incoherent range walk compensation technique is developed which focuses the power in the DDM on the iso-delay and iso-Doppler configuration occurring at the midpoint of the integration period. This is shown to mitigate the correlation losses associated with a point scatterer on the surface by over 6 dB that occur due to tracking strategies currently employed by state-of-the-art receivers. An adaptive window for stare processing which regularises the spatial footprint and reduces the variance of the extracted profiles is developed. Then, the ambiguous stare processing concept is introduced and a simulation study demonstrates sensitivity to wind direction on a spaceborne platform can be achieved. Multiple techniques applicable to target detection are developed. The first observation of persistent non-specular coherent scattering off an ice sheet is followed by the development of an ice sheet detection method which exploits this. Furthermore, the method is able to integrate an arbitrary number of DDMs without inducing any loss of spatial resolution. Following this, sea target ambiguity resolution is demonstrated with a simulation study. Then, the application of an adaptive filter for blind sea clutter suppression is presented. Finally, a novel matched filter, capable of detecting targets in sequences of DDMs is developed. The sensitivity of the DDM to satellite attitude is investigated and the pitch of TDS-1 is estimated using DDMs produced on-orbit.

Similar Items