Title :
VHDL-AMS behavioral modeling and simulation of a Π/4 DQPSK transceiver system
Author :
Normark, Erik ; Yang, Lei ; Wakayama, Cherry ; Nikitin, Pavel ; Shi, Richard
Author_Institution :
Dept. of Electr. Eng., Washington Univ., Seattle, WA, USA
Abstract :
This work describes a methodology for top-down design, modeling, and simulation of complete Π/4 DQPSK system using hardware description language VHDL-AMS. Two system implementations are considered: with and without Viterbi encoder/decoder. VHDL-AMS implementations of various RF blocks (e.g. a realistic channel model) are developed, the system is simulated, and bit error rate is evaluated in the presence of noise. We show that the results of VHDL-AMS simulations for basic Π/4 DQPSK system in Mentor Graphics ADVance-MS match both Agilent ADS results and theoretical calculations. Adding a simple Viterbi encoder and decoder in VHDL to the basic system results in an approximate 1.4 dB SNR improvement. This work together is targeted towards engineers who work on behavioral modeling and simulation of complete RF systems using hardware description languages.
Keywords :
Viterbi decoding; circuit simulation; differential phase shift keying; error statistics; hardware description languages; integrated circuit modelling; quadrature phase shift keying; transceivers; Π/4 DQPSK transceiver system; Agilent ADS; Mentor Graphics ADVance-MS match; RF blocks; VHDL-AMS; Viterbi decoder; Viterbi encoder; behavioral modeling; bit error rate; hardware description language; realistic channel model; system simulation; AWGN; Additive white noise; Design methodology; Gaussian noise; Graphics; Hardware design languages; Radio frequency; System performance; Transceivers; Viterbi algorithm;
Conference_Titel :
Behavioral Modeling and Simulation Conference, 2004. BMAS 2004. Proceedings of the 2004 IEEE International
Print_ISBN :
0-7803-8615-9
DOI :
10.1109/BMAS.2004.1393993
