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Underwater Acoustic Communications
Navy STTR FY2005
| Sol No.: |
Navy STTR FY2005 |
| Topic No.: |
N05-T022 |
| Topic Title: |
Underwater Acoustic Communications |
| Proposal No.: |
N054-022-0459 |
| Firm: |
Heat, Light, and Sound Research, Inc.
12730 High Bluff Drive
Suite 130
San Diego, California 92130 |
| Contact: |
Paul Hursky |
| Phone: |
(858) 755-9649 |
| Web Site: |
http://www.hlsresearch.com/ |
| Abstract: |
The US Navy is increasingly looking to underwater acoustic communications as the basis for wireless networks for various missions. However, the underwater channel is a difficult one for communications, plagued by multipath and fading. The relatively slower propagation speed (compared to RF) makes Doppler a significant factor for mobile platforms and when signals are scattered from an ocean surface in motion due to waves. The bandwidth available for communication is severely limited by volume attenuation (to perhaps 100 kHz at ranges of 1-3 km) and our ability to design wideband transmitters. Current experimental signaling schemes for point-to-point communications achieve no more than 20 kbps*km throughput under the best of conditions, and are generally processed off-line in the laboratory. Commercial modem systems achieve much less throughput, with at times lower reliability. Multiple input multiple output (MIMO) signaling is an exciting new technology, only recently being adopted in RF wireless applications (e.g. 802-11n), that significantly improves communications performance and reliability. This MIMO (multiple input / multiple output) technique exploits a "rich" multipath environment by simultaneously transmitting across many independent virtual channels using the entire band (i.e. without multiplexing in time or frequency). Spectral efficiencies of 20-40 bits per second per Hertz have been demonstrated in the wireless community - such rates are not possible using traditional techniques. How this technique can be adapted to the underwater channel is the subject of this proposal. We propose to develop a MIMO modem that provides either significantly increased bit rates or greatly reduced error rates, depending on the modulation scheme, in typical shallow water ocean environments. In our Phase I effort, we will: 1) continue collecting data at sea as we push the performance envelope of our current MIMO algorithms, space-time trellis coding (STTC) with joint equalization and decoding and layered space time coding (LSTC) with iterative decoding and equalization, 2) develop strategies for making the modem operate autonomously, using in-modem channel measurements as the basis for automating all modem parameter settings, 3) develop a preliminary hardware design, to establish the feasibility of implementing the modem on a single board with FPGAs and DSP chips, to be ultimately integrated with a next-generation commercial modem. |
| Benefits: |
MIMO technology promises to provide greatly increased communication system performance, either in terms of data rate, or in terms of reduced error rates, compared to equivalent point-topoint signaling schemes. Making increased data rates available enables many new applications, such as networks of autonomous systems deployed in the ocean, to be used for ASW, harbor defence, ipeline inspection, etc. |
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