Experimental verification of optical backhaul links for high‐altitude platform networks: Atmospheric turbulence and downlink availability

Optical backhaul downlinks from high‐altitude platforms (HAPs) are investigated. An experiment demonstrated the advantages of optical links: a small and lightweight terminal with low power consumption was launched to the stratosphere and data transmitted down to a ground station at a rate of 1.25 Gbit/s. Owing to the chosen system parameters and the high budget margin, disturbing turbulence effects did not decrease the link performance. The scientific aspect of the experiment was to study turbulence effects in order to design future systems with higher transmission performance. On the day of the experiment, measured scintillation and wavefront distortions were minimal in the morning. The best atmospheric conditions were observed about 3 h after sunrise with a peak of the atmospheric coherence length r 0 at 16 cm. An r 0 of 4 cm was measured as the worst case before sunrise and later during the day. This trend could also be observed for power‐ ( $ {\sigma _P^2} $ ) and intensity scintillation index ( $ {\sigma _I^2} $ ). The latter $ {\sigma _I^2} $ changed from 0.28 (best case) to 1.12. For small $ {\sigma _I^2} $ , a lognormal intensity probability density function was measured. Apart from the robust intensity modulation scheme with direct detection which was used for the trial, future improved systems could benefit from a coherent transmission scheme. According to the r 0 measurements and further simulations on heterodyne efficiency it turned out that the aperture size can be decreased from 40 to 10 cm without any significant change in the link margin. Future stratospheric optical links between HAPs or links from platforms to satellites will not suffer from cloud blockage but it remains an issue for up/downlinks to a ground station. This can be mitigated by ground‐station diversity. Four optical ground stations in the southern part of Europe can lead to an availability of over 98%. The separation distance of the ground stations is about 900 km with a negligible correlation of cloud cover. A change of wavelength from the employed 1.55 to a wavelength around 11‐µm with minimum cloud attenuation would increase the link availability for thin clouds. Copyright © 2007 John Wiley & Sons, Ltd.