Received signal-level, characteristics of wide-band transmission in mobile communications

“…The model proposed in [4] assumes that multipath waves arrive at the receiver under the following conditions. Each of the arriving waves ( reflected and/or diffracted waves, plus an LoS one) has a path length , these being independent and uniformly distributed within a given range.…”

“…The bandwidth of each arriving wave is greater than the receiver bandwidth (2 , centered at the carrier frequency ) and the power spectral density is assumed to be flat and centered on . Thus, the received signal power can be obtained from [4] ( 1) where is the speed of light and represents the path-length difference between the th and th arriving waves.…”

“…A new propagation parameter, the equivalent received bandwidth defined as the product between the system bandwidth 2 and the maximum possible difference in the propagation path length among different arriving components , , thus, reflecting the influence of system bandwidth and environment characteristics, is also proposed in [4]. The value of depends on the radius of the cell, hence, even for the same system bandwidth, the signal level distribution depends on the type of the considered cellular environment.…”

“…An expression for the received signal level, under nonline-of-sight (NLoS) conditions, is derived and examined for various values of propagation parameters. A generalization of this model to the line-of-sight (LoS) case and the introduction of a new propagation parameter, the equivalent received bandwidth , defined as the product between the system bandwidth and the maximum difference in propagation path length, is presented in [4]- [6]. It was shown that this new parameter is closely related to the fading depth.…”

“…This approach, having the Rice factor as a parameter, is derived by fitting simulation data obtained from the model in [4]. The paper is organized as follows.…”

Fading depth dependence on system bandwidth in mobile communications-an analytical approximation

“…The model proposed in [4] assumes that multipath waves arrive at the receiver under the following conditions. Each of the arriving waves ( reflected and/or diffracted waves, plus an LoS one) has a path length , these being independent and uniformly distributed within a given range.…”

“…The bandwidth of each arriving wave is greater than the receiver bandwidth (2 , centered at the carrier frequency ) and the power spectral density is assumed to be flat and centered on . Thus, the received signal power can be obtained from [4] ( 1) where is the speed of light and represents the path-length difference between the th and th arriving waves.…”

“…A new propagation parameter, the equivalent received bandwidth defined as the product between the system bandwidth 2 and the maximum possible difference in the propagation path length among different arriving components , , thus, reflecting the influence of system bandwidth and environment characteristics, is also proposed in [4]. The value of depends on the radius of the cell, hence, even for the same system bandwidth, the signal level distribution depends on the type of the considered cellular environment.…”

“…An expression for the received signal level, under nonline-of-sight (NLoS) conditions, is derived and examined for various values of propagation parameters. A generalization of this model to the line-of-sight (LoS) case and the introduction of a new propagation parameter, the equivalent received bandwidth , defined as the product between the system bandwidth and the maximum difference in propagation path length, is presented in [4]- [6]. It was shown that this new parameter is closely related to the fading depth.…”

“…This approach, having the Rice factor as a parameter, is derived by fitting simulation data obtained from the model in [4]. The paper is organized as follows.…”

Fading depth dependence on system bandwidth in mobile communications-an analytical approximation

A Time-Domain Based Approach for Short-Term Fading Depth Evaluation in Wideband Mobile Communication Systems

Received signal-level characteristics in a wide-band mobile radio channel