The evolution to a well-expected technology in wireless-communications maturity is in progress. Complementary applications are being suggested for such purposes, which might be possibly effective from the already ongoing research on high-altitude-platform systems. Herein, we introduce a HAPS-based system for delivering broadband communications intended to be operational at L band. A physical-statistical channel model for the HAPSto-fixed-terrestrial terminal provision is derived from urban geometrical radio-coverage considerations with a simple diffraction theory. The stratospheric broadband channel model is fulfi lled with the two channel-state situations related to the direct and specular rays, plus multipath. The fi rst state consists of predicting the performance for which the line-of-sight path can exist between HAPS and the still terminal at street level. The second channel state refers to modeling the statistical fading characteristics for the shadowing condition. The system implementation is approximated and analyzed by performing intensive simulation-aided modeling. The proposed hypotheses use empirical data derived from land-mobile-satellite communication-system records. Because the systems require robust, reliable, and future standardization results, IEEE 802.16™-2004 PHYlayer technical specifi cations are used to accomplish the WiMAX HAPS-based downlink performance evaluation.

Peer Reviewed