ELE Master of Science Thesis Defense by Justin Conor (ECE)
When: Thursday,
December 14, 2023
2:00 PM
-
4:00 PM
Where: > See description for location
Cost: Free
Description: Topic: Experimental Measurements and Model Validation of The Scattering Function of An Underwater Multiple Highlight Acoustic Body
Location: Lester W. Cory Conference Room, Science & Engineering Building (SENG), Room 213A
Abstract:
Acoustic Target strength (TS) of an object is a measure of the net reflection coefficient of that object and is generally a function of both incident and scattered directions as well as frequency. For each pair of directions at each frequency the TS is the ratio of the acoustic pressure incident on the object due to a harmonic plane wave to the acoustic pressure of the reflected far field observation direction (but referenced to 1 meter from the acoustic center of the object). Active sonar systems use scattered field measurements to detect the presence of an underwater object. For this reason, target strength modeling is fundamental to the development of active sonar systems such as bathymetric profiling and mobile target detection. The model must accurately capture the echo response of the scattering body. This response can be simulated from a coherent summation of multiple individual feature scatterer responses known as highlights. Highlights can be represented in the form of simple shapes such as spheres and cylinders. Increasing the number of highlights for a given object can increase the fidelity of the model, at the cost of increased model complexity. Such complexities can additionally increase the uncertainty in the model validation process. This thesis advances the goal of an optimal level of model fidelity with an acceptable minimal level of model output uncertainty. This work compares observed underwater target strength measurements of a multi highlight scattering body against outputs from two different target strength scattering models while identifying key areas of uncertainty associated with random platform motion and possibly refraction effects that typically attend real acoustic measurement. Presented here are target strength measurements across the full range of incident and scattered look directions at small wavelengths relative to target size. We show quantitative and qualitative correspondence between modeled and observed target strength measures. Results reveal that the unmodeled effects of platform motion and multipath scattering as well as angle stability of the target frame degrade model fidelity. Additional sources of uncertainty are the necessary censoring of support cable reflections as well as the unknown scattering features of the target present in the observed data. These are qualitatively assessed. We report approximately 22% accuracy at a 90% confidence level, over an aspect range of 200 degrees. For aspect angles, 110 to 130 degrees, the models were most accurate.
Advisor(s): Dr. Paul J. Gendron, Associate Professor, Department of Electrical & Computer Engineering, UMASS Dartmouth
Committee Members:
Dr. David A. Brown, Professor, Department of Electrical & Computer Engineering, UMASS Dartmouth
Dr. Dayalan P. Kasilingam, Chairperson & Professor, Department of Electrical & Computer Engineering, UMASS Dartmouth
Dr. Edward H. Pees, Engineer, Naval Undersea Warfare Center (NUWC)
NOTE: All ECE Graduate Students are ENCOURAGED to attend.
All interested parties are invited to attend. Open to the public.
*For further information, please contact Dr. Paul Gendron via email at pgendron@umassd.edu
Location: Lester W. Cory Conference Room, Science & Engineering Building (SENG), Room 213A
Abstract:
Acoustic Target strength (TS) of an object is a measure of the net reflection coefficient of that object and is generally a function of both incident and scattered directions as well as frequency. For each pair of directions at each frequency the TS is the ratio of the acoustic pressure incident on the object due to a harmonic plane wave to the acoustic pressure of the reflected far field observation direction (but referenced to 1 meter from the acoustic center of the object). Active sonar systems use scattered field measurements to detect the presence of an underwater object. For this reason, target strength modeling is fundamental to the development of active sonar systems such as bathymetric profiling and mobile target detection. The model must accurately capture the echo response of the scattering body. This response can be simulated from a coherent summation of multiple individual feature scatterer responses known as highlights. Highlights can be represented in the form of simple shapes such as spheres and cylinders. Increasing the number of highlights for a given object can increase the fidelity of the model, at the cost of increased model complexity. Such complexities can additionally increase the uncertainty in the model validation process. This thesis advances the goal of an optimal level of model fidelity with an acceptable minimal level of model output uncertainty. This work compares observed underwater target strength measurements of a multi highlight scattering body against outputs from two different target strength scattering models while identifying key areas of uncertainty associated with random platform motion and possibly refraction effects that typically attend real acoustic measurement. Presented here are target strength measurements across the full range of incident and scattered look directions at small wavelengths relative to target size. We show quantitative and qualitative correspondence between modeled and observed target strength measures. Results reveal that the unmodeled effects of platform motion and multipath scattering as well as angle stability of the target frame degrade model fidelity. Additional sources of uncertainty are the necessary censoring of support cable reflections as well as the unknown scattering features of the target present in the observed data. These are qualitatively assessed. We report approximately 22% accuracy at a 90% confidence level, over an aspect range of 200 degrees. For aspect angles, 110 to 130 degrees, the models were most accurate.
Advisor(s): Dr. Paul J. Gendron, Associate Professor, Department of Electrical & Computer Engineering, UMASS Dartmouth
Committee Members:
Dr. David A. Brown, Professor, Department of Electrical & Computer Engineering, UMASS Dartmouth
Dr. Dayalan P. Kasilingam, Chairperson & Professor, Department of Electrical & Computer Engineering, UMASS Dartmouth
Dr. Edward H. Pees, Engineer, Naval Undersea Warfare Center (NUWC)
NOTE: All ECE Graduate Students are ENCOURAGED to attend.
All interested parties are invited to attend. Open to the public.
*For further information, please contact Dr. Paul Gendron via email at pgendron@umassd.edu
Contact: > See Description for contact information
Topical Areas: General Public, University Community, College of Engineering, Electrical and Computer Engineering