Title :
LPI in pulsed laser space communications
Author :
Gagliardi, Robert M.
Author_Institution :
Commun. Sci. Inst., Univ. of Southern California, Los Angeles, CA, USA
fDate :
6/1/1993 12:00:00 AM
Abstract :
A basic low-probability of intercept (LPI) study for a pulsed-laser pulse position modulated (PPM) optical link with a colocated direct detection intercepting receiver is presented. The latter is considered to be a form of optical radiometer using continuous threshold testing to detect the presence of the transmitting laser. The various design alternatives for the coded PPM link, and their effect on the communication and LPI performance, are examined. It is shown that the use of optical pulse power spreading via multiple frame symbol coding is vital for avoiding interception. It can be achieved by transmitting message symbols as repeated PPM symbols using a laser pulse of sufficiently low peak power so that the detected pulse energy is much less than the detected background energy. The possibility of the use of both wideband and narrowband radiometers by the interceptor further limits the communicator´s code design choices. Some equations defining effective LIP gain parameters for the communication link are developed
Keywords :
laser beam applications; optical links; optical modulation; pulse position modulation; LPI; PPM optical link; background energy; communication link; continuous threshold testing; direct detection intercepting receiver; gain parameters; low-probability of intercept; multiple frame symbol coding; narrowband radiometers; optical pulse power spreading; optical radiometer; peak power; pulse energy; pulse position modulated; pulsed laser space communications; transmitting laser; Narrowband; Optical fiber communication; Optical modulation; Optical pulses; Optical receivers; Power lasers; Pulse modulation; Radiometry; Testing; Wideband;
Journal_Title :
Selected Areas in Communications, IEEE Journal on
