مرکز منطقه ای اطلاع رساني علوم و فناوري - The effect of attenuation on the capacity of a photon channel

Abstract :

The process of attenuation of electromagnetic energy when transmitted over some communication channel is stochastic in nature. Hence one can expect that, since equivocation is imposed in the transmission, in addition to reduction of average signal power, there will be a consequent degradation in channel capacity. We have attempted to calculate the effect of this phenomenon on an otherwise noiseless photon channel and when the source itself is assumed to have no undesired fluctuations. In order to do so, we have employed a straightforward variational technique and introduced the partition function method of statistical mechanics to obtain an expression for channel capacity. Using approximate methods, we find that the maximum information transfer is achieved when the probability of receiving exactly $k$ photons goes down, asymptotically with large $k$ , as $e^{-ck}/ \\sqrt {k}$ , where $c$ is a positive constant. For very large received average energy $U$ (in photon number), the channel capacity behaves approximately as $C = frac{1}{2} \\ln U$ , one-half the capacity of an ideal noiseless photon channel (given by Gordon\´s formula for the capacity of an electromagnetic wave). For very small received average energy, we find that the (optimum) received distribution is very nearly Bose-Einstein, and the channel capacity is not degraded below its ideal value. The results are applicable to an idealized laser oscillator and also to photoelectric detection. That is, both devices by themselves may be regarded as "channels" for which the input may be modulated as desired and the output is stochastically dependent on the input.