Title :
Design and performance evaluation of a 2.5-GSPS digital receiver
Author :
Chen, Chien-In Henry ; George, Kiran ; McCormick, William ; Tsui, James B Y ; Hary, Stephen L. ; Graves, Keith M.
Author_Institution :
Dept. of Electr. Eng., Wright State Univ., Dayton, OH, USA
fDate :
6/1/2005 12:00:00 AM
Abstract :
Today´s very deep submicron IC technology enables high-performance analog and digital applications to be integrated on a single piece of silicon. For this effort, a design of 2.5 giga-sample per second (GSPS) receiver-on-a-chip (ROC) is presented. For our design, we take advantage of a compensation technique to reduce spurs and improve instantaneous dynamic range. A major goal is to produce a low-cost, small, and lightweight, and low-power ROC. Our design will cover a 1-GHz bandwidth (125 - 1125 MHz), and it will correctly process two simultaneous signals by detecting their frequency, pulsewidth (PW), and time of arrival (TOA). The single or dual signal, spur-free dynamic ranges and two signal instantaneous dynamic ranges of our design are high. The minimum frequency separation of two signals is 10 MHz (one channel width), and the maximum amplitude separation (dynamic range) of two signals is 18 dB with the second signal false alarm less than 1%.
Keywords :
compensation; integrated circuit design; performance evaluation; receivers; system-on-chip; digital receiver; performance evaluation; receiver-on-a-chip; very deep submicron IC technology; Analog integrated circuits; Application specific integrated circuits; Bandwidth; Digital integrated circuits; Dynamic range; Frequency; Signal design; Signal detection; Signal processing; Silicon; Digital receiver; false alarm; fast Fourier transform (FFT); radio frequency; single signal dynamic range; two signal instantaneous dynamic range; two signal spur free dynamic range;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
DOI :
10.1109/TIM.2005.847206
