Title :
A method for estimating intensity and impulse response functions of filtered Poisson processes
Author :
Mino, Hiroyuki ; Matsumoto, Masanobu ; Yana, Kazuo
Author_Institution :
Dept. of Inf. Sci., Toho Univ., Chiba, Japan
fDate :
10/1/1997 12:00:00 AM
Abstract :
This paper presents a method for estimating the intensity and impulse response (IR) function of filtered Poisson processes. The case is considered where the filtered Poisson process is modeled as an output of the linear constant-coefficient ordinary differential equations having poles and zeros driven by Poisson impulse processes. It is shown that an explicit formula for estimating the intensity is derived by combining second-and third-order cumulants of the residual time series generated from the discretized filtered Poisson process. It is also shown that the IR function can be estimated from the parameters of the discretized filtered Poisson process. Then, Monte Carlo simulations demonstrate the validity of the proposed method in some specific examples. It is concluded that the proposed method can be extensively applied to actual phenomena appearing in engineering and science
Keywords :
Monte Carlo methods; autoregressive moving average processes; differential equations; estimation theory; filtering theory; parameter estimation; signal processing; stochastic processes; transient response; IR function; Monte Carlo simulation; autoregressive moving average process; discretized filtered Poisson process; engineering; filtered Poisson processes; impulse response functions; linear constant-coefficient ordinary differential equations; poles and zeros; residual time series; science; second-order cumulants; third-order cumulants; Autoregressive processes; Differential equations; Diodes; Frequency; Neuromuscular; Nonlinear filters; Parameter estimation; Poisson equations; Poles and zeros; Vacuum systems;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
