Emitter identification using optical processors

Hartup, David Carl

12 1900

No description available.

Array processors

Radar Antennas

A low cost vision system for landmark tracking

McKinney, William Sigsbee

12 1900

No description available.

Detectors

Tracking radar

New target detector based on geometrical perturbation filters for polarimetric Synthetic Aperture Radar (POL-SAR)

Marino, Armando

January 2010

Synthetic Aperture Radar (SAR) is an active microwave remote sensing system able to acquire high resolution images of the scattering behaviour of an observed scene. The contribution of SAR polarimetry (POLSAR) in detection and classification of objects is described and found to add valuable information compared to previous approaches. In this thesis, a new target detection/classification methodology is developed that makes novel use of the polarimetric information of the backscattered field from a target. The detector is based on a geometrical perturbation filter which correlates the target of interest with its perturbed version. Specifically, the operation is accomplished with a polarimetric coherence representing a weighted and normalised inner product between the target and its perturbed version, where the weights are extracted from the observables. The mathematical formulation is general and can be applied to any deterministic (point) target. However, in this thesis the detection is primarily focused on multiple reflections and oriented dipoles due to their extensive availability in common scenarios. An extensive validation against real data is provided exploiting different datasets. They include one airborne system: E-SAR L-band (DLR, German Aerospace Centre); and three satellite systems: ALOS-PALSAR L-band (JAXA, Japanese Aerospace Exploration Agency), RADARSAT-2 C-band (Canadian Space Agency) and TerraSAR-X X-band (DLR). The attained detection masks reveal significant agreement with the expected results based on the theoretical description. Additionally, a comparison with another widely used detector, the Polarimetric Whitening Filter (PWF) is presented. The methodology proposed in this thesis appears to outperform the PWF in two significant ways: 1) the detector is based on the polarimetric information rather than the amplitude of the return, hence the detection is not restricted to bright targets; 2) the algorithm is able to discriminate among the detected targets (i.e. target recognition).

621.3848

radar ; polarimetry detection

Signal processing for airborne bistatic radar

Ong, Kian P.

January 2003

The major problem encountered by an airborne bistatic radar is the suppression of bistatic clutter. Unlike clutter echoes for a sidelooking airborne monostatic radar, bistatic clutter echoes are range dependent. Using training data from nearby range gates will result in widening of the clutter notch of STAP (space-time adaptive processing) processor. This will cause target returns from slow relative velocity aircraft to be suppressed or even go undetected. Some means of Doppler compensation for mitigating the clutter range dependency must be carried out. This thesis investigates the nature of the clutter echoes with different radar configurations. A novel Doppler compensation method using Doppler interpolation in the angle-Doppler domain and power correction for a JDL (joint domain localized) processor is proposed. Performing Doppler compensation in the Doppler domain, allows several different Doppler compensations to be carried out at the same time, using separate Doppler bins compensation. When using a JDL processor, a 2-D Fourier transformation is required to transform space-time domain training data into angular-Doppler domain. Performing Doppler compensation in the spacetime domain requires Fourier transformations of the Doppler compensated training data to be carried out for every training range gate. The whole process is then repeated for every range gate under test. On the other hand, Fourier transformations of the training data are required only once for all range gates under test, when using Doppler interpolation. Before carrying out any Doppler compensation, the peak clutter Doppler frequency difference between the training range gate and the range gate under test, needs to be determined. A novel way of calculating the Doppler frequency difference that is robust to error in pre-known parameters is also proposed. Reducing the computational cost of the STAP processor has always been the desire of any reduced dimension processors such as the JDL processor. Two methods of further reducing the computational cost of the JDL processor are proposed. A tuned DFT algorithm allow the size of the clutter sample covariance matrix of the JDL processor to be reduced by a factor proportional to the number of array elements, without losses in processor performance. Using alternate Doppler bins selection allows computational cost reduction, but with performance loss outside the clutter notch region. Different systems parameters are also used to evaluate the performance of the Doppler interpolation process and the JDL processor. Both clutter range and Doppler ambiguity exist in radar systems operating in medium pulse repetitive frequency mode. When suppressing range ambiguous clutter echoes, performing Doppler compensation for the clutter echoes arriving from the nearest ambiguous range alone, appear to be sufficient. Clutter sample covariance matrix is estimated using training data from the range or time or both dimension. Investigations on the number of range and time training data required for the estimation process in both space-time and angular-Doppler domain are carried out. Due to error in the Doppler compensation process, a method of using the minimum amount of range training data is proposed. The number of training data required for different clutter sample covariance matrix sizes is also evaluated. For Doppler interpolation and power correction JDL processor, the number of Doppler bins used can be increased, to reduce the amount of training data required, while maintaining certain desirable processor performance characteristics.

623.7

PhD Thesis ; radar

Analysis and application of differential propagation phase shift in polarization-diversity radar measurements of precipitation at centimeter wavelengths

Tan, Jun

January 1991

No description available.

621.37

Radar meteorology

Using statistical methods for automatic classifications of clouds in ground-based photographs of the sky

Arshad, Irshad Ahmad

January 2003

No description available.

551

Weather radar images

Analysis and application of polarisation diversity radar data

McGuinness, R.

January 1984

No description available.

621.3848

Radar data analysis

Analysis of resistive-vee dipole antennas for producing polarization diversity

Sustman, James William

27 August 2014

This thesis presents a new dual circularly polarized antenna for ground penetrating radar applications. The new antenna design uses four crossed Resistive-Vee Dipoles (RVD) operating in bistatic mode to measure multiple polarizations. The antenna system is able to distinguish radially symmetric and linear targets with its ability to transmit right-hand circularly polarized (RHCP) fields and receive both left-hand circularly polarized (LHCP) and RHCP scattered fields. The type of target can be identified by comparing the relative amplitudes of the received LHCP fields and RHCP fields. For example, linear targets such as wires may be identified by equal amounts of scattered LHCP and RHCP fields. Numerical modeling was used to optimize the arrangement of the four RVDs in the RVD-based CP antenna to have low coupling and good circular polarization at close range. The resulting antenna design is shown to be very effective at finding buried wire targets without being costly. Additional modeling was performed to improve the circular polarization by changing the arm shape and resistive profile of the RVDs. Three methods are developed for estimating the spatial orientation angle of a detected wire target. The first method involves synthesizing transmission and reception of linear polarization at many angles to find the angle that matches the angle of the wire target. The second and third methods involve directly computing the angle of the wire target from the phase difference in the co-polarization and cross-polarization responses. All three methods provide accurate estimates. The RVD-based CP antenna enables strong detection of subsurface targets along with geometry-based classification of targets. The RVD-based CP antenna is well suited for finding buried wires and rejecting miscellaneous clutter that may be present in the ground.

Radar

Polarization

Dipole

Direct frequency synthesis using combined digital and analogue techniques

Jones, William John

January 1988

No description available.

621.3848

Radar detection

The application of digital techniques to an automatic radar track extraction system

Spearman, Richard R.

January 1988

'Modern' radar systems have come in for much criticism in recent years, particularly in the aftermath of the Falklands campaign. There have also been notable failures in commercial designs, including the well-publicised 'Nimrod' project which was abandoned due to persistent inability to meet signal processing requirements. There is clearly a need for improvement in radar signal processing techniques as many designs rely on technology dating from the late 1970's, much of which is obsolete by today’s standards. The Durham Radar Automatic Track Extraction System (RATES) is a practical implementation of current microprocessor technology, applied to plot extraction of surveillance radar data. In addition to suggestions for the design of such a system, results are quoted for the predicted performance when compared with a similar product using 1970's design methodology. Suggestions are given for the use of other VLSI techniques in plot extraction, including logic arrays and digital signal processors. In conclusion, there is an illustrated discussion concerning the use of systolic arrays in RATES and a prediction that this will represent the optimum architecture for future high-speed radar signal processors.

621.3848

Radar system processors