IN33C-1811
An airborne robotic platform for mapping thermal structure in surface water bodies
Wednesday, 16 December 2015
Poster Hall (Moscone South)
Sally E Thompson1, Michaella Chung2, Carrick Detweiler3 and John-Paul Ore3, (1)University of California Berkeley, Civil and Environmental Engineering, Berkeley, CA, United States, (2)University of California Berkeley, Berkeley, CA, United States, (3)University of Nebraska, Lincoln, Computer Science and Engineering, Lincoln, NE, United States
Abstract:
The significance of thermal heterogeneities in small surface water bodies as drivers of mixing and for habitat provision is increasingly recognized, yet obtaining three-dimensionally resolved observations of the thermal structure of lakes and rivers remains challenging. For relatively shallow water bodies, observations of water temperature from aerial platforms are attractive: they do not require shoreline access, they can be quickly and easily deployed and redeployed, facilitating repeated sampling, and they can rapidly move between measurement locations, allowing multiple measurements to be made during single flights. However, they are also subject to well-known limitations including payload, flight duration and operability, and their effectiveness as a mobile platform for thermal sensing is still poorly characterized. In this talk, I will introduce an aerial thermal sensing platform that enables water temperature measurements to be made and spatially located throughout a water column, and present preliminary results from initial field experiments comparing in-situ temperature observations to those made from the UAS platform. The results highlight the potential scalability of the platform to provide high-resolution 3D thermal mapping of a ~1 ha lake in 2-3 flights (circa 1 hour), sufficient to resolve diurnal variations. Operability constraints and key needs for further development are also identified.