Terahretz Channel Modeling in ULEO Satellite-to-Ground Communications
Abstract
The exponential growth in satellite data traffic demands communication systems exceeding current microwave capacity limitations, while the terahertz (THz) frequency band (0.1-10 THz) offers unprecedented bandwidth potential with superior weather resilience compared to optical systems, particularly when combined with ultra-low Earth orbit (ULEO) satellite deployments below 300 km altitude. This article presents comprehensive channel modeling and performance evaluation for ULEO-THz satellite-to-ground communications, analyzing three distinct transmission architectures (direct satellite-to-ground, satellite-relay-ground forwarding, and satellite-to-high altitude base station with fiber backhaul) through altitude-resolved atmospheric propagation models validated using year-long meteorological data from four high-altitude stations in Tibet and Qinghai, China. The analysis incorporates frequency-dependent atmospheric absorption using ITU-R standards, free-space path loss with curved atmospheric modeling, and regional atmospheric variations to derive total channel path loss, available bandwidth capacity, and bit error rate (BER) performance under both AWGN and Weibull fading conditions across multiple THz frequencies. Results demonstrate that direct satellite-to-ground transmission at lower THz frequencies achieves optimal practical performance with maximum available bandwidth under QPSK modulation, while satellite-relay-ground forwarding suffers prohibitive cumulative losses from multiple hops, and satellite-to-high altitude base station configurations, despite favorable atmospheric channel characteristics, become impractical due to substantial electro-optical conversion penalties and fiber transmission losses in long-haul applications.