Open Access  Subscription or Fee Access

Pulse compression technique is most widely used in radar and communication areas. The radar pulse compression codes must have good merit factor and discrimination factor. But there are several signal design problems which are reported in the literature and these signal design problems can be solved through binary, Ter-nary, Quinquenary and six phase pulse compression sequences. Hence VLSI architectures to generate such radar pulse compression sequences were developed. But when we are moving from binary to ternary and ternary to six phase pulse compression VLSI systems, the memory requirements are increased there by the area is increased. The good VLSI design needs optimization of the area, speed, power consumption. This paper concentrates on developing area optimized VLSI architecture to generate radar pulse compression sequences without sacrificing the speed of the system. The other interesting thing about this paper is the proposed single chip VLSI architecture can generate all the phase coded pulse compression sequences like Binary, Ternary, Quaternary, Quinquenary, 6-phase and other poly phase sequences. The VLSI architecture is implemented on the Field Programmable Gate Array (FPGA) as it provides the flexibility of reconfigurability and reprogrammability.

FPGA, Merit Factor, PULSE Compression, Side Lobe Energy, Six Phase Pulse Compression.

E. C. Farnett and G. H. Stevens, “Pulse compression radar,” Radar Handbook, Second ed. New York: McGraw-Hill,1990.

Golay M J E 1977 Sieves for low autocorrelation binary se-quences. EEE Trans. Inf. Theory IT-23: 43-51

Barker R H 1953 Group synchronization of binary digital systems. In Communication theory (ed.) W Jackson (London: Butterworths).

Pasha, I. A., Moharir, P. S., and Nelatury, S. R., “Bi- alphabetic pulse compression radar signal design,” Sadhana, Proceedings of the Indian Academy of Sciences, vol. 25, no. 5, 2000, pp. 481-488.

Bernasconi J “Low autocorrelation binary sequences: statistical me-chanics and configuration space analysis. J. Phys. 48: 559-567

De Groot C, Wurtz D, Hoffman K H 1992 Low autocorrelation binary sequences: exact enumeration and optimization by evolutionary strate-gies Optimization 23: 369-384

Turyn R 1963 Optimum code study. Sylvania Electric Systems Rep. F 437-1

Turyn R 1968 Sequences with small correlation. In Error correcting codes (ed.) H B Mann (New York: Wiley) pp 195-228

Baumert L D 1971 Cyclic difference sets (Berlin: Springer-Verlag) Cook C E, Bernfeld M 1967 Radar signals (New York: Academic Press.

Golay M J E 1972 A class of finite binary sequences with alternate autocorrelation values equal to zero. IEEE Trans. Inf. Theory IT-18: 449-450

Golay M J E 1982 The merit factor of long low autocorrelation binary sequences. IEEE Trans. Inf.Theory IT-28: 543-549

Golay M J E 1983 The merit factor of Legendre sequences. IEEE Trans. Inf. Theory IT-29: 934-936.

Moharir P S 1975 Generation of the approximation to binary white noise. J. IETE 21:5-7.

Beenker G F M, Claasen T A C M, Heime P W C 1985 Binary se-quences with a maximally flat amplitude spectrum. Phillips J. Res. 40: 289-304

Kerdock A M, Meyar R, Bass D 1986 Longest binary pulse compres-sion codes with given peak side lobe levels. Proc. IEEE 74: 366

Bernasconi J 1988 Optimization problems and statistical mechanics. Proc. Workshop on Chaos and Complexity, 1987 (Torino: World Scientific).

Hoholdt T, Jensen H E, Justesen J 1985 Aperiodic correlations and the merit factor of a class of binary sequences. IEEE Trans. Inf. Theory IT-31: 549-552.

Hoholdt T, Justesen J 1988 Determination of the merit factor of Le-gendre¬ sequences. IEEE Trans.Inf. Theory IT-34: 161-164.

Golay M J E, Harris D 1990 A new search for skew-symmetric binary sequences with optimal merit factors. IEEE Trans. Inf. Theory 36: 1163-1166.

Newmann D J, Byrnes J S 1990 The L norm of polynomial with coef-ficientsá1. Am. Math. Mon.97: 42-45

Jensen J M, Jensen H E, Hoholdt T 1991 The merit factor of binary sequences related to difference sets. IEEE Trans. Inf. Theory IT-37: 617-626

Singh R, Moharir P S, Maru V M 1996 Eugenic algorithm-based search for ternary pulse compression sequences. J. Inst. Electron. Te-lecommun. Eng. 42: 11-19

Moharir P S, Maru V M, Singh R 1998 Simonization for signal design. Sadhana 23: 351-358

Moharir P S, Maru V M, Singh R 1996 S-K-H algorithm for signal design. Electron. Lett. 32:1648-1649.

Arthur, J.W.: 'Modern SAW-based pulse compression systems for radar applications. Part 2: Practical systems‟, Electron. & Commun. Eng. April 1996, 7, (6), pp.237-246

Day R., Germon R., O'Neill B., 1997A Pulse Compression Radar Signal Processor, IEE Colloquim on DSP Chip's in Real Time Instru-mentation and Display Systems 4/1-4/5

Day, R.H. Germon, R. O'Neill, B.C. 1998 A real time digital signal processing solution for radar pulse compression” IEE Colloquium on Digital Filters: An Enabling Technology 6/1-6/5.

Balaji .N, Subba Rao. K and Srinivasa Rao.M “Generation of Non-binary pulse compression sequences using FPGA”, in Proc. of Inter-national conference on VLSI design and Embedded Systems (ICVLSI‟08), pp.221-225, 2008.

Balaji .N, Subba Rao. K and Srinivasa Rao.M “Generation of Pulse compression sequences using FPGA”, in Proc. of International confe-rence on RF and Signal Processing Systems (RSPS-2008), pp.279-285, 2008.

Balaji .N, Subba Rao. K and Srinivasa Rao.M , “Generation of Quin-quenary Pulse Compression Sequences using FPGA” in Proc. of the 8th WSEAS International conference on Multimedia Systems and Signal Processing (MUSP '08), pp.280-286, 2008.

N. Balaji, K. Subba Rao, M.Srinivasa Rao 2010 A Real Time Signal Processing Solution for the Binary Pulse Compression Sequences with Good Merit Factor values, IEEE, pp.(353-357).

N. Balaji, K. Subba Rao, M.Srinivasa Rao 2010 FPGA Implementa-tion of Ternary Pulse Compression Sequences with Superior Merit Factor

N. Balaji, K. Subba Rao, M.Srinivasa Rao 2010 Real Time Genera-tion of the Quinquenary Pulse Compression Sequence using FPGA”, ACTA ELECTROTECHNICA, pp.(18-24).

N. Balaji, K. Subba Rao, M.Srinivasa Rao 2010 Generation of “Six phase Pulse Compression Sequences using FPGA” in Proc. Interna-tional Conference on Computer Science and Information Technology, pp. 829-835,2008.

[35] Xilinx, Spartan-3 Field Programmable Gate array data sheets (http://www.xilinx.com/spartan3).