Coherent and Nonlinear Lightwave CommunicationsThis is a practical source on recent developments in coherent and nonlinear lightwave communications. The book systematically presents up-to-date explanations of all the relevant physical principles and recent research in this emerging area. Providing an unparallelled engineering-level treatment (with 700 equations), this reference also describes the progression of coherent and nonlinear technology from yesterday's experimental field to today's practical applications tool. This work is intended as a tool for research telecommunication engineers, applications engineers working with broadband telecom systems and networks, and postgraduate students. |
From inside the book
Results 1-3 of 24
Page 198
... Gaussian pulses provides at least 50 % more transmission rate than solitons with the same energy . Another advantage is related to pulse generation . It is well known that the generation of Gaussian pulses is simpler than generation of ...
... Gaussian pulses provides at least 50 % more transmission rate than solitons with the same energy . Another advantage is related to pulse generation . It is well known that the generation of Gaussian pulses is simpler than generation of ...
Page 280
... Gaussian process [ 6 ] , then the assemblage of samples , v1 ( to ) , will also be a Gaussian process with some mean value S. The probabil- ity density function for such a case is w1 ( v ) = 1 ( v – - √2 TO , exp ( - ( P = 5 ) 2 ) 2πσι ...
... Gaussian process [ 6 ] , then the assemblage of samples , v1 ( to ) , will also be a Gaussian process with some mean value S. The probabil- ity density function for such a case is w1 ( v ) = 1 ( v – - √2 TO , exp ( - ( P = 5 ) 2 ) 2πσι ...
Page 298
... Gaussian distribution , 121 Gaussian error function , 25 , 279 , 280 Gaussian pulses , 197-98 with equivalent energy , 198 parameters , 197 propagation of , 197 transmission of , 198 Gordon - Haus effect , 199 Gordon - Haus time jitter ...
... Gaussian distribution , 121 Gaussian error function , 25 , 279 , 280 Gaussian pulses , 197-98 with equivalent energy , 198 parameters , 197 propagation of , 197 transmission of , 198 Gordon - Haus effect , 199 Gordon - Haus time jitter ...
Other editions - View all
Common terms and phrases
amplification coefficient amplitude applied binary Brillouin scattering channels Chapter characteristics coherent detection coherent lightwave system coherent optical receiver components corresponding crystal DCPSK digit interval dispersion DPSK electric field electro-optical ellipsoid energy equal equation erbium-doped fiber amplifiers error probability evaluated expressed Figure filter frequency bandwidth Gaussian Hence homodyne detection IEEE IEEE/OSA IM/DD incoming optical signal influence input laser amplifiers length Lett lightwave systems Lightwave Techn loss modulating signal modulation methods nonlinear effects nonlinear lightwave system obtained optical amplifiers Optical Commun optical oscillator optical power optical receiver optical transmitter optical-fiber parameters phase difference phase modulation phase noise phase shift photodetector photodiode photons polarization propagation PSK signals pump signal Raman amplification Raman amplifiers random ratio realization receiver sensitivity refractive index resonator semiconductor laser signal power single-mode optical fiber soliton pulse soliton regime spontaneous emission thermal noise transmission system variance voltage wavelength