Author_Institution :
Dept. of Electr. Eng., Wichita State Univ., KS, USA
Abstract :
A digital communication receiver, called a third-generation receiver, has been developed. This receiver takes samples of the direct-sequence spread signal at a nonzero intermediate frequency (IF) instead of the zero IF (baseband), and quantizes the samples by employing a 1-b analog-to-digital (A/D) converter at the receiver front end. These 1-b samples are digitally processed for pseudonoise (PN) code, carrier, bit synchronization, and bit decision with the use of an application-specific integrated circuit. The effects of the IF sampling and 1-b A/D conversion on PN code synchronization are analyzed for a PN spread-spectrum communication system with oversampling rate, e.g., 12 samples per chip. In addition, the bit-error rate (BER) degradation due to the 1-b A/D conversion is studied by assuming perfect PN code, carrier, and bit synchronization. It is observed that the BER degradation due to the 1-b A/D is significant, e.g., 2.4 dB, when decimation is made after IF sampling such that only one sample per chip is used for bit decision. These analyzed BER results agree well with the simulated results. However, if no decimation is made and oversampling is used for bit decision, BER degradation due to 2-b A/D conversion is insignificant, e.g., 0.6 dB
Keywords :
analogue-digital conversion; application specific integrated circuits; coding errors; data communication; digital radio; error statistics; pseudonoise codes; quantisation (signal); radio receivers; satellite tracking; signal sampling; spread spectrum communication; synchronisation; ADC; BER degradation; DS-SS; IF sampling; PN code synchronization; Tracking Data Relay Satellite Systems; application-specific integrated circuit; bit decision; carrier synchronization; digital communication receiver; direct sequence spread signal samples; direct sequence spread spectrum; intermediate frequency; oversampling; pseudonoise code; quantization; receiver front end; third-generation TDRSS; Analog-digital conversion; Application specific integrated circuits; Baseband; Bit error rate; Degradation; Digital communication; Frequency conversion; Frequency synchronization; Sampling methods; Spread spectrum communication;
