Translator Disclaimer
2 May 2000 Design of the optoelectronic receiver for deep-space optical communications
Author Affiliations +
Proceedings Volume 3932, Free-Space Laser Communication Technologies XII; (2000)
Event: Symposium on High-Power Lasers and Applications, 2000, San Jose, CA, United States
The opto-electronic receiver (detector and pre-amplifier) necessary to meet the demands of high capacity deep space missions is designed for a Mars-Earth optical communication link. The receiver requirements are driven by link performance (data rate, bit-error rate, margin), delivered power, pulse width, background signal, telescope quality, and atmospheric effects. Meeting these requirements becomes more challenging as the mission range and the demand for link capacity increases. In this article, the detector's characteristics (e.g. quantum efficiency, noise, gain, and diameter) are designed to address these various requirements. The receiver sensitivity's dependence on the background noise power and on the APD detector's characteristics is analyzed. The improvement in opto- electronic receiver sensitivity is quantified for improvements in APD quantum efficiency, ionization factor, and bulk dark current. It is also found that as the background signal increases the improvement on the receiver sensitivity from an improved detector is diminished due to the quantum noise limit. An opto-electronic receiver is designed based on a Silicon APD to meet the mission requirement of a PPM (M equals 256) 30 kbps data rate (BER of 10-5) link. Improvements to the APD detector are also studied to describe a design that would achieve over 50 kbps data rates for a Mars-Earth optical communication link.
© (2000) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Gerry G. Ortiz, John V. Sandusky, and Abhijit Biswas "Design of the optoelectronic receiver for deep-space optical communications", Proc. SPIE 3932, Free-Space Laser Communication Technologies XII, (2 May 2000);

Back to Top