The low-cost packet radio

Research on packet switched radio networks requires reconfigurable testbeds with large numbers of readily deployable radios. This motivated the development of a small, low-cost packet radio (LPR) with the flexibility to support extensive network experiments, and to be amenable to tailoring to specific end-use applications. The LPR incorporates a digitally controlled direct sequence minimum shift keyed spread-spectrum radio and a microprocessor-based packet switch. Code changeable surface acoustic wave (SAW) matched filtering provides processing gain at burst symbol rates of 100k and 400k symbols per second in the presence of interference. Coherent recursive integration enhances synchronization performance, provides synchronous detection of the data, and serves the adaptive multipath accumulator. Forward error correction utilizing convolutional encoding and sequential decoding is incorporated at four different code rates for both burst symbol rates. The microprocessor runs the networking software. Requirements, design, and performance data for the LPR engineering model are presented.

[1]  F. G. Herring,et al.  Low Cost, Miniature, Programmable SAW Matched Filter for Tactical Spread Spectrum Systems , 1983, MILCOM 1983 - IEEE Military Communications Conference.

[2]  M. H. Enein Coherent Signal Processing for Packet Radio , 1982, MILCOM 1982 - IEEE Military Communications Conference - Progress in Spread Spectrum Communications.

[3]  George L. Turin The effects of multipath and fading on the performance of direct-sequence CDMA systems , 1984, IEEE Transactions on Vehicular Technology.

[4]  Fouad A. Tobagi,et al.  Multiaccess Protocols in Packet Communication Systems , 1980, IEEE Trans. Commun..

[5]  S.A. Gronemeyer,et al.  Advances in packet radio technology , 1978, Proceedings of the IEEE.

[6]  W. A. Kissick,et al.  A Guide to the Use of the ITS Irregular Terrain Model in the Area Prediction Mode , 1982 .

[7]  D. Behrman,et al.  A Low-Cost Spread-Spectrum Packet Radio , 1982, MILCOM 1982 - IEEE Military Communications Conference - Progress in Spread Spectrum Communications.

[8]  G.L. Turin,et al.  Introduction to spread-spectrum antimultipath techniques and their application to urban digital radio , 1980, Proceedings of the IEEE.

[9]  D. V. Sarwate,et al.  Error Probability for Direct-Sequence Spread-Spectrum Multiple-Access Communications - Part I: Upper and Lower Bounds , 1982, IEEE Transactions on Communications.

[10]  Kung Yao,et al.  Error Probability of Asynchronous Spread Spectrum Multiple Access Communication Systems , 1977, IEEE Trans. Commun..

[11]  E. A. Geraniotis,et al.  Error Probability for Direct-Sequence Spread-Spectrum Multiple-Access Communications - Part II: Approximations , 1982, IEEE Transactions on Communications.

[12]  A. G. Longley,et al.  PREDICTION OF TROPOSPHERIC RADIO TRANSMISSION LOSS OVER IRREGULAR TERRAIN. A COMPUTER METHOD-1968 , 1968 .

[13]  S. Pasupathy,et al.  Minimum shift keying: A spectrally efficient modulation , 1979, IEEE Communications Magazine.

[14]  Stephen T. Kent,et al.  Security Mechanisms in High-Level Network Protocols , 1983, CSUR.

[15]  F. Amoroso,et al.  Simplified MSK Signaling Technique , 1977, IEEE Trans. Commun..