Wireless Flexible Personalized Communications
Wireless Flexible Personalized Communications
A Dynamic Model of the Indoor Channel
Wireless Personal Communications: An International Journal
A time-variant MIMO channel model directly parametrised from measurements
EURASIP Journal on Wireless Communications and Networking - Special issue on advances in propagation modelling for wireless systems
Detection and tracking of MIMO propagation path parameters using state-space approach
IEEE Transactions on Signal Processing
Modeling the ultra-wideband outdoor channel: measurements and parameter extraction method
IEEE Transactions on Wireless Communications
A novel wideband dynamic directional indoor channel model based on a Markov process
IEEE Transactions on Wireless Communications
The COST259 Directional Channel Model-Part I: Overview and Methodology
IEEE Transactions on Wireless Communications
A Measurement-Based Fading Model for Wireless Personal Area Networks
IEEE Transactions on Wireless Communications - Part 2
Statistical analysis of measured impulse response functions of 2.0 GHz indoor radio channels
IEEE Journal on Selected Areas in Communications
Channel parameter estimation in mobile radio environments using the SAGE algorithm
IEEE Journal on Selected Areas in Communications
A stochastic multipath channel model including path directions for indoor environments
IEEE Journal on Selected Areas in Communications
Hi-index | 0.00 |
The multipath components of superwideband (2-17.2GHz) nonline-of-sight channel responses measured inside several buildings are stable along sections that are 27 cm long on average with a standard deviation of 16 cm. The stability regions of multipath components have an approximately log-normal histogram. An analysis of measured channels that explicitly includes finite spatial areas of visibility of the multipath components is superior to the classic analysis that attributes spatial dynamics to interference of the multipath. The spatial stability of measured responses, that is, the size of the typical area of visibility of each multipath component, decreases as the carrier frequency increases but does not depend on bandwidth. The results offer insight into the nature of the diffuse part of the radio channel.