Title :
On the design of LDPC codes for MSK
Author :
Narayanan, K.R. ; Altunbas, I. ; Narayanaswami, R.
Author_Institution :
Dept. of Electr. Eng., Texas A&M Univ., College Station, TX, USA
Abstract :
We investigate serial concatenation of low-density parity check (LDPC) codes and minimum shift keying (MSK) with iterative decoding. We show that the design of LDPC codes is crucially dependent on the realization of the MSK modulator. For MSK modulators with nonrecursive continuous phase encoders (CPEs), optimal codes for BPSK are optimal, whereas for MSK modulators with recursive CPEs, the BPSK codes are not optimal. We show that for nonrecursive CPEs, iterative demodulation and decoding is not required even though the CPE has memory. However, iterative demodulation is essential for recursive CPEs. For recursive CPEs, we design LDPC codes using density evolution and differential evolution considering iterative demodulation and decoding. The resulting codes provide significantly improved performance over the existing codes
Keywords :
concatenated codes; continuous phase modulation; demodulation; iterative decoding; minimum shift keying; phase shift keying; BPSK; LDPC codes; MSK; density evolution; differential evolution; iterative decoding; iterative demodulation; low-density parity check codes; minimum shift keying; nonrecursive continuous phase encoders; recursive continuous phase encoders; serial concatenation; AWGN; Binary phase shift keying; Bit error rate; Concatenated codes; Continuous phase modulation; Convolutional codes; Demodulation; Iterative decoding; Modulation coding; Parity check codes;
Conference_Titel :
Global Telecommunications Conference, 2001. GLOBECOM '01. IEEE
Conference_Location :
San Antonio, TX
Print_ISBN :
0-7803-7206-9
DOI :
10.1109/GLOCOM.2001.965570
