Radio-transparent multi-layer insulation for radiowave receivers

Choi, Jihoon; Ishitsuka, H.; Mima, Silvana; Oguri, S.; Takahashi, Kohki; Tajima, O.

doi:10.1063/1.4827081

Cited by 37 publications

(27 citation statements)

References 12 publications

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“…This system facilitates repeat calibration. A technique for blocking infra-red radiation also is crucial to this system [1]. Noise temperature of our prototype cold receiver as a function of frequency.…”

Section: Kumodes: a Measurement System For Atmospheric Radiation Specmentioning

confidence: 99%

Monitoring System for Atmospheric Water Vapor with a Ground-Based Multi-Band Radiometer: Meteorological Application of Radio Astronomy Technologies

Nagasaki

Araki²,

Ishimoto³

et al. 2015

J Low Temp Phys

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High-resolution estimation of thermodynamic properties in the atmosphere can help to predict and mitigate meteorological disasters, such as local heavy rainfall and tornadic storms. For the purposes of short-term forecasting and nowcasting of severe storms, we propose a novel ground-based measurement system, which observes the intensity of atmospheric radiation in the microwave range. Our multi-band receiver system is designed to identify a rapid increase in water vapor before clouds are generated. At frequencies between 20 and 30 GHz, our system simultaneously measures water vapor as a broad absorption peak at 22 GHz as well as cloud liquid water. Another band at 50-60 GHz provides supplementary information from oxygen radiation to give vertical profiles of physical temperature. For the construction of this cold receiver system, novel technologies originally developed for observations of cosmic microwave background radiation were applied. The input atmospheric signal is amplified by a cold low-noise amplifier maintained below 10 K, while the spectrum of this amplified signal is measured using a signal analyzer under ambient conditions. The cryostat also contains a cold black body at 40 K to act as a calibration signal. This calibration signal is transported to each of the receivers via a wire grid. We can select either the atmospheric signal or the calibration signal by changing the orientation of this wire. Each receiver can be calibrated using this setup. Our system is designed to be compact (<1 m 3 ), with low power consumption (∼1.5 kW). Therefore, it is easy to deploy on top of high buildings, mountains, and ship decks. B T. Nagasaki

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Section: Kumodes: a Measurement System For Atmospheric Radiation Specmentioning

confidence: 99%

Monitoring System for Atmospheric Water Vapor with a Ground-Based Multi-Band Radiometer: Meteorological Application of Radio Astronomy Technologies

Nagasaki

Araki²,

Ishimoto³

et al. 2015

J Low Temp Phys

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“…More details are described elsewhere. 1,5,6 A CMB instrument with a large throughput requires a large window. The large window results in a large thermal loading to each thermal stage.…”

Section: Metal Meshmentioning

confidence: 99%

“…When a lens with such a large diameter is made of Ultra High Molecular Weight Polyethylene (UHMWPE), like POLARBEAR-1 (PB-1), the lens must be highly curved due to the low index of refraction (IOR) of ∼1. 5. The steep incident angle to the lens surface is not ideal for use in polarimetry.…”

Section: Introductionmentioning

confidence: 98%

Thermal and optical characterization for POLARBEAR-2 optical system

et al. 2014

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Downloaded From: http://proceedings.spiedigitallibrary.org/ on 05/15/2015 Terms of Use: http://spiedl.org/terms ABSTRACT POLARBEAR-2 (PB-2) is a cosmic microwave background (CMB) polarization experiment for B-mode detection. The PB-2 receiver has a large focal plane and aperture that consists of 7588 transition edge sensor (TES) bolometers at 250 mK. The receiver consists of the optical cryostat housing reimaging lenses and infrared filters, and the detector cryostat housing TES bolometers. The large focal plane places substantial requirements on the thermal design of the optical elements at the 4K, 50K, and 300K stages. Infrared filters and lenses inside the optical cryostat are made of alumina for this purpose. We measure basic properties of alumina, such as the index of refraction, loss tangent and thermal conductivity. All results meet our requirements. We also optically characterize filters and lenses made of alumina. Finally, we perform a cooling test of the entire optical cryostat. All measured temperature values satisfy our requirements. In particular, the temperature rise between the center and edge of the alumina infrared filter at 50 K is only 2.0 ± 1.4 K. Based on the measurements, we estimate the incident power to each thermal stage.

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“…The diameter of the aperture window is 30 cm. For thermal radiation shielding from the aperture, a combination of metal mesh filters (QMC Instruments Ltd.) and radio-transform multi-layer insulations (RT-MLI) was used [15]. The RT-MLI is a novel thermal radiation blocker, i.e., stacked layers of formed-polystyrene.…”

Section: Cooling Of Receiver Cryostatmentioning

confidence: 99%

GroundBIRD: Observing Cosmic Microwave Polarization at Large Angular Scale with Kinetic Inductance Detectors and High-Speed Rotating Telescope

Oguri

Choi²,

Damayanthi

et al. 2015

J Low Temp Phys

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Cosmic microwave background (CMB) is an important source of information about the origin of our universe. In particular, odd-parity large angular scale patterns in the CMB polarization, the primordial B-modes, are strong evidence for an inflationary universe, related to the accelerating expansion of the metric. We are developing a unique telescope, GroundBIRD, to take CMB polarization measurements. The telescope combines novel techniques: high-speed rotation scanning, cold optics, and microwave kinetic inductance detectors (MKIDs). We evaluated the response of MKIDs on the rotation stage. Method of shielding from the geo-magnetic field is established. We have also developed a receiver cryostat. We are able to maintain a sufficient cold status for observations on the optical configuration. We plan to start commissioning the system by observing CMB in Japan in 2015-2016. We will then deploy GroundBIRD in the Canary Islands for further scientific observations. B S. Oguri

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Radio-transparent multi-layer insulation for radiowave receivers

Cited by 37 publications

References 12 publications

Monitoring System for Atmospheric Water Vapor with a Ground-Based Multi-Band Radiometer: Meteorological Application of Radio Astronomy Technologies

Monitoring System for Atmospheric Water Vapor with a Ground-Based Multi-Band Radiometer: Meteorological Application of Radio Astronomy Technologies

Thermal and optical characterization for POLARBEAR-2 optical system

GroundBIRD: Observing Cosmic Microwave Polarization at Large Angular Scale with Kinetic Inductance Detectors and High-Speed Rotating Telescope

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