Title :
Reduced complexity iterative demodulation and decoding of serial concatenated continuous phase modulation
Author :
Shane, Mark R. ; Wesel, Richard D.
Author_Institution :
Aerosp. Corp., El Segundo, CA, USA
Abstract :
We present a structure for reduced complexity iterative demodulation and decoding of partial response continuous phase modulation (CPM) when serially concatenated with a convolutional code. The proposed receiver uses a single front-end filter and a 2 or 4 state trellis for decoding the inner CPM code. This can yield a significant savings, as the complexity of the optimal demodulator increases exponentially with the length of the CPM frequency pulse. Simulations show that for GMSK with BT = 1/6, the performance penalty for simplified iterative demodulation and decoding is less than 0.25 dB, compared to the receiver which performs optimal demodulation (which requires 32 filters and a 64 state inner trellis).
Keywords :
computational complexity; concatenated codes; continuous phase modulation; demodulation; filtering theory; iterative decoding; matched filters; minimum shift keying; CPM frequency pulse; CPW; GMSK; Laurent decomposition; convolutional code; front-end filter; inner CPM code; inner code trellis; matched filters; optimal demodulation; optimal demodulator; partial response continuous phase modulation; performance penalty; radio channels; reduced complexity iterative decoding; reduced complexity iterative demodulation; serial concatenated continuous phase modulation; serially concatenated code; simulations; state trellis decoding; Concatenated codes; Continuous phase modulation; Convolution; Convolutional codes; Demodulation; Filters; Frequency; Iterative decoding; Modulation coding; Pulse modulation;
Conference_Titel :
Communications, 2002. ICC 2002. IEEE International Conference on
Print_ISBN :
0-7803-7400-2
DOI :
10.1109/ICC.2002.997133
