"Time of flight measurements for optically illuminated underwater targets using Compressive Sampling and Sparse reconstruction"
| Title | "Time of flight measurements for optically illuminated underwater targets using Compressive Sampling and Sparse reconstruction" |
| Publication Type | Conference Paper |
| Year of Publication | 2015 |
| Authors | R. Lee, L. Mullen, P. Pal, D. Illig |
| Conference Name | OCEANS 2015 - MTS/IEEE Washington |
| Date Published | Oct |
| Publisher | IEEE |
| ISBN Number | 978-0-9339-5743-5 |
| Accession Number | 15798755 |
| Keywords | Bandwidth, Chirp, compressed sensing, compressive sampling, compressive sensing theory, down-conversion signal processing method, FMCW Lidar, Frequency Chirp, Frequency modulation, high resolution time of flight measurement, Laser radar, linearly frequency modulated continuous wave hybrid lidar system, linearly frequency modulated continuous wave hybrid radar system, marine radar, matched filter signal processing method, matched filters, mixing signal processing method, Nyquist sampling theorem, optical radar, optically illuminated underwater target, pubcrawl170104, radar resolution, Receivers, Sensors, signal reconstruction, Signal resolution, Sparse Reconstruction, sparse reconstruction theory, turbid underwater environment, turbidity |
| Abstract | Compressive Sampling and Sparse reconstruction theory is applied to a linearly frequency modulated continuous wave hybrid lidar/radar system. The goal is to show that high resolution time of flight measurements to underwater targets can be obtained utilizing far fewer samples than dictated by Nyquist sampling theorems. Traditional mixing/down-conversion and matched filter signal processing methods are reviewed and compared to the Compressive Sampling and Sparse Reconstruction methods. Simulated evidence is provided to show the possible sampling rate reductions, and experiments are used to observe the effects that turbid underwater environments have on recovery. Results show that by using compressive sensing theory and sparse reconstruction, it is possible to achieve significant sample rate reduction while maintaining centimeter range resolution. |
| URL | http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=7404393&isnumber=7401802 |
| DOI | 10.23919/OCEANS.2015.7404393 |
| Citation Key | 7404393 |
- matched filters
- turbidity
- turbid underwater environment
- sparse reconstruction theory
- Sparse Reconstruction
- Signal resolution
- signal reconstruction
- sensors
- Receivers
- radar resolution
- pubcrawl170104
- optically illuminated underwater target
- optical radar
- Nyquist sampling theorem
- mixing signal processing method
- Bandwidth
- matched filter signal processing method
- marine radar
- linearly frequency modulated continuous wave hybrid radar system
- linearly frequency modulated continuous wave hybrid lidar system
- Laser radar
- high resolution time of flight measurement
- Frequency modulation
- Frequency Chirp
- FMCW Lidar
- down-conversion signal processing method
- compressive sensing theory
- compressive sampling
- compressed sensing
- Chirp