Ben Moshe, D., Messer, H., Werber, Y., and Sapir, N. 2024. Cellular network measurements can unravel spatiotemporal properties of bird movement to enhance basic and applied knowledge globally. Ornithological Applications 126:duae035. doi: http://doi.org/10.1093/ornithapp/duae035
ABSTRACT
A major problem in studying bird movement in many countries is data scarcity, precluding information about the spatial and temporal properties
of avian distribution and dynamics as well as their consequences for human lives. We address this problem by proposing an innovative approach
based on the relation between counts of signal attenuation of wireless communication to the presence of birds across or near wireless links of
cellular backhaul networks. Wireless point-to-point communication links, on either ground level or earth-satellite links, cover the globe. We statistically relate between signal attenuation in terrestrial Commercial Microwave Links (CMLs) and bird migration. Because modern communication
systems measure and often log signal levels routinely, we propose using existing signal level measurements of cellular and other wireless communication systems around the world as sensors for monitoring bird movement. Using actual measurements from operational CMLs, we show that the daily cycle of signal attenuation during bird migration periods matched that of the water-bird migration traffic rate recorded by nearby
bird radar. This demonstrates the potential of the proposed method for opportunistic bird movement monitoring by CMLs across the globe, with no additional hardware installation, maintenance, or communication costs.
of avian distribution and dynamics as well as their consequences for human lives. We address this problem by proposing an innovative approach
based on the relation between counts of signal attenuation of wireless communication to the presence of birds across or near wireless links of
cellular backhaul networks. Wireless point-to-point communication links, on either ground level or earth-satellite links, cover the globe. We statistically relate between signal attenuation in terrestrial Commercial Microwave Links (CMLs) and bird migration. Because modern communication
systems measure and often log signal levels routinely, we propose using existing signal level measurements of cellular and other wireless communication systems around the world as sensors for monitoring bird movement. Using actual measurements from operational CMLs, we show that the daily cycle of signal attenuation during bird migration periods matched that of the water-bird migration traffic rate recorded by nearby
bird radar. This demonstrates the potential of the proposed method for opportunistic bird movement monitoring by CMLs across the globe, with no additional hardware installation, maintenance, or communication costs.