TY - GEN
T1 - Analytic expressions for the Rice Ie-function and the incomplete Lipschitz-Hankel Integrals
AU - Sofotasios, Paschalis C.
AU - Freear, Steven
PY - 2011
Y1 - 2011
N2 - This paper presents novel analytic expressions for the Rice Ie-function, Ie(k, x), and the incomplete Lipschitz-Hankel Integrals (ILHIs) of the modified Bessel function of the first kind, Ie m, n(a, z). Firstly, an exact infinite series and an accurate polynomial approximation are derived for the Ie(k, x) function which are valid for all values of k. Secondly, an exact closed-form expression is derived for the Ie m, n(a, z) integrals for the case that n is an odd multiple of 1/2 and subsequently an infinite series and a tight polynomial approximation which are valid for all values of m and n. Analytic upper bounds are also derived for the corresponding truncation errors of the derived series'. Importantly, these bounds are expressed in closed-form and are particularly tight while they straightforwardly indicate that a remarkable accuracy is obtained by truncating each series after a small number of terms. Furthermore, the offered expressions have a convenient algebraic representation which renders them easy to handle both analytically and numerically. As a result, they can be considered as useful mathematical tools that can be efficiently utilized in applications related to the analytical performance evaluation of classical and modern digital communication systems over fading environments, among others.
AB - This paper presents novel analytic expressions for the Rice Ie-function, Ie(k, x), and the incomplete Lipschitz-Hankel Integrals (ILHIs) of the modified Bessel function of the first kind, Ie m, n(a, z). Firstly, an exact infinite series and an accurate polynomial approximation are derived for the Ie(k, x) function which are valid for all values of k. Secondly, an exact closed-form expression is derived for the Ie m, n(a, z) integrals for the case that n is an odd multiple of 1/2 and subsequently an infinite series and a tight polynomial approximation which are valid for all values of m and n. Analytic upper bounds are also derived for the corresponding truncation errors of the derived series'. Importantly, these bounds are expressed in closed-form and are particularly tight while they straightforwardly indicate that a remarkable accuracy is obtained by truncating each series after a small number of terms. Furthermore, the offered expressions have a convenient algebraic representation which renders them easy to handle both analytically and numerically. As a result, they can be considered as useful mathematical tools that can be efficiently utilized in applications related to the analytical performance evaluation of classical and modern digital communication systems over fading environments, among others.
KW - approximations
KW - Bessel functions
KW - error probability
KW - fading channels
KW - Incomplete Lipschitz-Hankel Integrals
KW - Marcum Q-function
KW - performance evaluation
KW - Rice Ie-function
UR - http://www.scopus.com/inward/record.url?scp=84857224127&partnerID=8YFLogxK
U2 - 10.1109/INDCON.2011.6139504
DO - 10.1109/INDCON.2011.6139504
M3 - Conference contribution
AN - SCOPUS:84857224127
SN - 9781457711091
T3 - Proceedings - 2011 Annual IEEE India Conference: Engineering Sustainable Solutions, INDICON-2011
BT - Proceedings - 2011 Annual IEEE India Conference
T2 - 2011 Annual IEEE India Conference: Engineering Sustainable Solutions, INDICON-2011
Y2 - 16 December 2011 through 18 December 2011
ER -