Title: MISTiC Winds, a Distributed Architecture Approach to Dynamic Weather Observations
Presenting Author: Kevin Robert Maschhoff
Organization: BAE Systems

Abstract:
MISTiC Winds is an approach based on a miniature high resolution, wide field, thermal emission spectrometry instrument that will provide global tropospheric vertical profiles of atmospheric temperature and humidity at high (3-4 km) spatial resolution. Its extraordinarily small size, low mass, and minimal cooling requirements can be accommodated aboard a small micro-satellite. Low fabrication and launch costs enable a LEO sun-synchronous sounding constellation that would collectively provide frequent (1-2 hour) sounding refresh rates or frequent, vertically resolved, tropospheric wind observations. These observations are highly complementary to present and emerging environmental observing systems, and would provide a combination of high vertical and horizontal resolution not provided by any other environmental observing system currently in operation. These observations, when assimilated into high resolution weather models, would revolutionize short-term and severe weather forecasting, save lives, and support key economic decisions in the utility, air transport industry, and agriculture – at much lower cost than providing these observations from GEO. In addition, this observation capability would be a critical tool in the study of transport processes for water vapor, clouds, pollution, and aerosols. The key technical risks in meeting these objectives relate to providing accurate, precise radiometry within the limited accommodations of a micro-satellite. Under the Instrument Incubator Program, we plan to reduce risk through integrating and demonstrating the calibration stability of our advanced, miniature dispersive infrared spectrometer in the laboratory, and in high-altitude airborne observations of 3-D cloud-drift and water vapor motion vector winds, (advancing TRL from 4-6). We will reduce component risk through space radiation tolerance testing of a critical new APD-Mode High Operating Temperature IRFPA that allows substantially reduced instrument power. This innovative approach, utilizing state of the art sensor technology in a novel architecture, will make critical new atmospheric state and transport observations affordable to the nation.