Space-Time Coding for Aeronautical Telemetry: Part II—Decoder and System Performance

This paper describes the use of Alamouti-encoded-shaped offset QPSK version TG (SOQPSK-TG) to solve the two-antenna problem in aeronautical telemetry. The Alamouti space-time block code is used to encode the phase states in the complex exponential representation of SOQPSK-TG. Because SOQPSK-TG possesses memory, the Alamouti decoder is a sequence estimator. Maximum likelihood and least squares sequence decoders are derived. To reduce the number of states, the eight-waveform cross-correlated trellis-coded quadrature modulation (XTCQM) approximate representation of SOQPSK-TG is used. A prototype decoder based on the least squares decoder and the estimators described in Part I and operating at a data rate of 10 Mb/s was tested in the laboratory in test flights at the Air Force Test Center, Edwards AFB. The test flights demonstrate that Alamouti-encoded SOQPSK-TG, as described in this paper, using the least squares decoder based on the estimators described in Part I solves the two antenna problem in aeronautical telemetry.

[1]  Robert Schober,et al.  Equalization concepts for Alamouti's space-time block code , 2004, IEEE Transactions on Communications.

[2]  Khaled Ben Letaief,et al.  Single-carrier frequency-domain equalization with decision-feedback processing for time-reversal space-time block-coded systems , 2005, IEEE Transactions on Communications.

[3]  Robert P. Jefferis LINK AVAILABILITY AND BIT ERROR CLUSTERS IN AERONAUTICAL TELEMETRY , 1999 .

[4]  M. Rice,et al.  Detection of Alamouti Encoded Shaped Offset QPSK , 2007, MILCOM 2007 - IEEE Military Communications Conference.

[5]  Erik Perrins,et al.  FEC Systems for Aeronautical Telemetry , 2013, IEEE Transactions on Aerospace and Electronic Systems.

[6]  A. Robert Calderbank,et al.  Finite-length MIMO decision feedback equalization for space-time block-coded signals over multipath-fading channels , 2001, IEEE Trans. Veh. Technol..

[7]  Michael Rice,et al.  Space-Time Coding for Aeronautical Telemetry: Part I—Estimators , 2017, IEEE Transactions on Aerospace and Electronic Systems.

[8]  Arogyaswami Paulraj,et al.  A transmit diversity scheme for channels with intersymbol interference , 2000, 2000 IEEE International Conference on Communications. ICC 2000. Global Convergence Through Communications. Conference Record.

[9]  T. Aulin,et al.  Continuous Phase Modulation - Part I: Full Response Signaling , 1981, IEEE Transactions on Communications.

[10]  Suhas N. Diggavi,et al.  Algebraic properties of space-time block codes in intersymbol interference multiple-access channels , 2003, IEEE Trans. Inf. Theory.

[11]  Michael Rice,et al.  Near Optimal Common Detection Techniques for Shaped Offset QPSK and Feher's QPSK , 2008, IEEE Transactions on Communications.

[12]  Mohammad Saquib,et al.  Equalization in aeronautical telemetry using multiple transmit antennas , 2015, IEEE Transactions on Aerospace and Electronic Systems.

[13]  Michael Rice,et al.  Space-Time Coding for Aeronautical Telemetry: Part II - Experimental Results , 2011 .

[14]  Marvin Kenneth Simon,et al.  Bandwidth-Efficient Digital Modulation with Application to Deep Space Communications , 2003 .

[15]  M.A. Jensen,et al.  Aeronautical telemetry using multiple-antenna transmitters , 2007, IEEE Transactions on Aerospace and Electronic Systems.

[16]  T. Aulin,et al.  Continuous Phase Modulation - Part II: Partial Response Signaling , 1981, IEEE Transactions on Communications.

[17]  A. Robert Calderbank,et al.  Space-Time block codes from orthogonal designs , 1999, IEEE Trans. Inf. Theory.

[18]  Michael Rice,et al.  Reduced-Complexity Approach to Iterative Detection of Coded SOQPSK , 2007, IEEE Transactions on Communications.

[19]  Michael Rice Space-Time Coding for Aeronautical Telemetry: Part I - System Description , 2011 .