Distributed MIMO Patrick Maechler April 2, 2008.

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Presentation transcript:

Distributed MIMO Patrick Maechler April 2, 2008

Outline Motivation: Collaboration scheme achieving optimal capacity scaling Distributed MIMO Synchronization errors Implementation Conclusion/Outlook

Throughput Scaling Scenario: Dense network TDMA/FDMA/CDMA: T(n) = O(1) Fixed area with n randomly distributed nodes Each node communicates with random destination node at rate R(n). Total throughput T(n) = nR(n) TDMA/FDMA/CDMA: T(n) = O(1) Multi-hop: T(n) = O( ) P. Gupta and P. R. Kumar, “The capacity of wireless networks,” IEEE Trans. Inf. Theory, vol. 42, no. 2, pp. 388–404, Mar. 2000. Hierarchical Cooperation: T(n) = O(n) Ayfer Özgür, Olivier Lévêque and David N. C. Tse, ”Hierarchical Cooperation Achieves Optimal Capacity Scaling in Ad Hoc Networks”, IEEE Trans. Inf. Theory, vol. 53, no. 10, pp. 3549-3572, Oct. 2007

Cooperation Scheme All nodes are divided into clusters of equal size Phase 1: Information distribution Each node splits its bits among all nodes in its cluster

Cooperation Scheme Phase 2: Distributed MIMO transmissions All bits from source s to destination d are sent simultaneously by all nodes in the cluster of the source node s

Cooperation Scheme Phase 3: Cooperative decoding The received signal in all nodes of the destination cluster is quantized and transmitted to destination d. Node d performs MIMO decoding.

Hierarchical Cooperation The more hierarchical levels of this scheme are applied, the nearer one can get to a troughput linear in n.

Outline Motivation: Collaboration scheme achieving optimal capacity scaling Distributed MIMO Synchronization errors Implementation Conclusion/Outlook

Distributed MIMO Independent nodes collaborate to operate as distributed multiple-input multiple-output system Simple examples: Receive MRC (1xNr): Transmit MRC (Ntx1, channel knowledge at transmitter) Alamouti (2xNr): STBC over 2 timeslots Diversity gain but no multiplexing gain Alamouti, S.M., "A simple transmit diversity technique for wireless communications ," Selected Areas in Communications, IEEE Journal on , vol.16, no.8, pp.1451-1458, Oct 1998

MIMO Schemes Schemes providing multiplexing gain: V-BLAST: Independent stream over each antenna D-BLAST: Coding across antennas gives outage optimality (higher receiver complexity) [1] P. W. Wolniansky, G. J. Foschini, G. D. Golden, and R. A. Valenzuela. V-BLAST: An architecture for realizing very high data rates over the rich scattering wireless channel. In ISSSE International Symposium on Signals, Systems, and Electronics, pages 295-300, Sept. 1998. [2] G. Foschini. Layered space-time architecture for wireless communication in a fading environment when using multi-element antennas. Bell Labs Technical Journal, 1(2):41-59, 1996.

MIMO Decoders Maximum likelihood: Zero Forcing / Decorrelator MMSE Balances noise and multi stream interference (MSI) Successive interference cancelation (SIC)

Error Rate Comparison MMSE-SIC is the best linear receiver ML receiver is optimal

Outline Motivation: Collaboration scheme achieving optimal capacity scaling Distributed MIMO Synchronization errors Implementation Conclusion/Outlook

Synchronization Each transmit node has its own clock and a different propagation delay to destination No perfect synchronization possible.  Shifted peaks at receiver What is the resulting error, if any?

Simulation results Flat fading channel assumed at receiver No large BER degradiation for timing errors up to 20% of symbol duration (raised cosine with )

Frequency-selectivity Synchronization errors make flat channels appear as frequency-selective channels Receivers for freq.-sel. channels can perfectly compensate synchronization errors Implementation cost is much higher!

Time Shift - SIC Promising results for SIC receiver that samples each stream at the optimal point Compensation of synchronization errors possible for independent streams (V-BLAST)

Outline Motivation: Collaboration scheme achieving optimal capacity scaling Distributed MIMO Synchronization errors Implementation Conclusion/Outlook

Implementation Goal: Show feasibility of distributed MIMO Systems using BEE2 boards Focus on synchronization algorithms at receiver Timing synchronization Frequency synchronization Channel estimation Complex decoders required All linear decoders need matrix inversion

Implementation BEE2 implementation of 2x1 Alamouti (MISO) scheme currently under development

Outline Motivation: Collaboration scheme achieving optimal capacity scaling Distributed MIMO Synchronization errors Implementation Conclusion/Outlook

Conclusion/Outlook Standard flat-channel MIMO decoders useable for synchronization errors up to 20% of symbol duration More complex decoders can compensate different delays also for higher errors Outlook: BEE2 implementation of MIMO receiver Frequency synchronization methods Measure achievable BER on real system for given synchronization accuracy at transmitters