Classification of modulation modes using time-frequency methods

Author

Ketterer, Helmut ; Jondral, Friedrich ; Costa, Antonio H.

Author_Institution

Inst. fur Nachrichtentech., Karlsruhe Univ., Germany

Volume

5

fYear

1999

fDate

1999

Firstpage

2471

Abstract

This paper proposes a new technique for feature extraction of modulated signals which is based on a pattern recognition approach. The new algorithm uses the cross Margenau-Hill distribution, autoregressive modeling, and amplitude variations to detect phase shifts, frequency shifts, and amplitude shifts, respectively. Our method is capable of classifying PSK2, PSK4, PSK8, PSK16, FSK2, FSK4, QAM8 and OOK signals. Unlike most of the existing decision-theoretic approaches, no explicit a priori information is required by our algorithm. Consequently, the method is suitable for application in a general noncooperative environment. Furthermore, our approach is computationally inexpensive. Simulation results on both synthetic and “real world” short-wave signals show that our approach is robust against noise up to a signal-to-noise ratio (SNR) of approximately 10 dB. A success rate greater than 94 percent is obtained

Keywords

amplitude shift keying; autoregressive processes; feature extraction; frequency estimation; frequency shift keying; pattern recognition; phase shift keying; quadrature amplitude modulation; radiocommunication; signal classification; signal detection; statistical analysis; time-frequency analysis; FSK; FSK2; M-ary FSK; M-ary PSK; OOK signals; PSK16; PSK2; PSK4; PSK8; QAM8; SNR; amplitude shifts detection; amplitude variations; autoregressive modeling; carrier frequency estimation; computationally inexpensive method; cross Margenau-Hill distribution; decision-theoretic approaches; feature extraction; frequency shifts detection; general noncooperative environment; modulated signals; modulation modes classification; pattern recognition; phase shifts detection; real world short-wave signals; signal-to-noise ratio; simulation results; synthetic short-wave signals; time-frequency methods; Computational modeling; Feature extraction; Frequency shift keying; Noise robustness; Pattern recognition; Phase detection; Phase frequency detector; Signal to noise ratio; Time frequency analysis; Working environment noise;

fLanguage

English

Publisher

ieee

Conference_Titel

Acoustics, Speech, and Signal Processing, 1999. Proceedings., 1999 IEEE International Conference on

Conference_Location

Phoenix, AZ

ISSN

1520-6149

Print_ISBN

0-7803-5041-3

Type

conf

DOI

10.1109/ICASSP.1999.760631

Filename

760631