Simulating Electromagnetic Transfer Function from the Transmission Antennae to the Sensors Vicinity in LiteBIRD
SPACE TELESCOPES AND INSTRUMENTATION 2020 OPTICAL, INFRARED, AND MILLIMETER WAVE(2021)
Natl Inst Technol | Japan Aerosp Explorat Agcy
Abstract
The electromagnetic interference (EMI) is becoming an increasingly important factor in the spacecraft design equipped with highly sensitive detectors. This is particularly the case for LiteBIRD, in which the TES bolometers are exposed to space through the optical path. A particular concern is radiative interference caused by the X-band transmission during the ground communication. As the end-to-end verification test will be conducted in a later phase of the development, we need to derisk the concern early using simulation. In this report, we present the result of the EMI effects in the 1-GHz frequency range based on the electromagnetic simulation using a finite difference time domain (FDTD) solver. We modeled the dominant large structures of the spacecraft, calculated the spatial transmission of the antenna power, and estimated the electric field strength at the detector focal plane. The simulation results helped constrain aspects of the LiteBIRD satellite, such as the forward/backward ratio of the transmission antenna, to reduce the coupling between the antenna and the detectors.
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Key words
Cosmic microwave background,space program,millimeter-wave polarization,cryogenic telescope,Electromagnetic Compatibility,electromagnetic simulator
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