Efficient simulation of the impulse response of the indoor wireless optical channel

## Abstract It is well known that indoor wireless optical channels are limited not only in transmitted optical power, but also in signalling bandwidth. This bandwidth constraint arises due to multipath dispersion in indoor settings as well as due to response time limitations of optoelectronic compo

## Abstract This paper presents a simulation tool for the fast calculation of the impulse response on infrared (IR) wireless indoor channels. We used Phong's model to approximate the reflection pattern of the indoor surfaces upon which a Monte Carlo ray‐tracing method allows us to evaluate the impu

## Abstract This paper presents concentrator and lens models for the detector and emitter, respectively, upon which a Monte Carlo ray‐tracing algorithm allows the evaluation of impulse response on infrared (IR) wireless indoor channels. We also present computer simulation results that show the effe

## Abstract Two linear orthogonal polarizers are used to reduce the effects of ambient noise light in an indoor optical wireless receiver. Using a differential detector coupled with orthogonal polarizers, the interference arising from a fluorescent lamp driven by electronic ballasts is reduced by a

This model is adequate for fast simulation of erbium-doped fiber amplifiers U This work was performed as a part of the MONET consortium under DARPA funding agreement MDA 972-95-3-0027. † Previously with Bell Communications Research.