Title :
Hop-timing estimation for FH signals using a coarsely channelized receiver
Author :
Aydin, L. ; Polydoros, Andreas
Author_Institution :
Dept. of Electr. Eng., Univ. of Southern California, Los Angeles, CA, USA
fDate :
4/1/1996 12:00:00 AM
Abstract :
This paper addresses new hop-timing (epoch) estimation schemes which employ a coarsely channelized preprocessor in order to suppress the frequency and phase dependence in random frequency-hopping (FH) signals. Coarse channelization implies a bank of filters, covering the total spread bandwidth of the FH signal, whose number is much smaller than the size of the candidate hop frequency set. Linear and nonlinear combinations of preprocessor outputs are explored and compared. It is found that post-processing, rather than the size of the filter bank alone, is the determining factor on estimation performance. Performance evaluation is presented via both extensive computer simulations and analytical lower bounds. Comparisons with existing optimal and suboptimal systems are also provided
Keywords :
band-pass filters; filtering theory; frequency hop communication; maximum likelihood estimation; radio receivers; signal processing; telecommunication channels; timing; FH signals; analytical lower bounds; coarsely channelized receiver; computer simulations; epoch estimation; estimation performance; filter banks; hop frequency set; hop-timing estimation; linear combining techniques; maximum likelihood estimation; nonlinear combining techniques; optimal systems; performance evaluation; preprocessor outputs; random frequency-hopping signals; suboptimal systems; total spread bandwidth; Analytical models; Bandwidth; Channel bank filters; Filter bank; Frequency estimation; Frequency shift keying; Frequency synchronization; Parameter estimation; Performance analysis; Phase estimation;
Journal_Title :
Communications, IEEE Transactions on
