Title :
Shaping and non-equiprobable signaling for intensity-modulated signals
Author :
Shiu, Da-shan ; Kahn, Joseph M.
Author_Institution :
California Univ., Berkeley, CA, USA
Abstract :
Current results of shaping and non-equiprobable signaling developed for conventional electrical signals do not apply to intensity-modulated (IM) signals. We show that for IM signals the optimum shape of the constellation bounding region in N-dimensional (N-D) space is an N-D simplex. As N→∞, the maximum achievable shape gain is 1.33 dB in transmitted power, and the resulting marginal signaling distribution on the 1-D constituent constellation is exponential. We also investigate the trade-offs between shaping and its negative effects and find that a 1-dB shape gain can be achieved while incurring reasonable increases in peak-to-average power ratio and constellation expansion factor
Keywords :
exponential distribution; intensity modulation; telecommunication signalling; IM signals; constellation bounding region; constellation expansion factor; exponential distribution; intensity-modulated signals; marginal signaling distribution; maximum achievable shape gain; nonequiprobable signaling; optimum shape; peak-to-average power ratio; shaping codes; transmitted power; Baseband; Constellation diagram; Gain; Intensity modulation; Lattices; Optical fiber communication; Optical transmitters; Peak to average power ratio; Shape; Signal to noise ratio;
Conference_Titel :
Global Telecommunications Conference, 1998. GLOBECOM 1998. The Bridge to Global Integration. IEEE
Conference_Location :
Sydney,NSW
Print_ISBN :
0-7803-4984-9
DOI :
10.1109/GLOCOM.1998.775726
