Search

Your search keyword '"Natsuko M. Kato"' showing total 21 results
Start Over Author "Natsuko M. Kato"
21 results on '"Natsuko M. Kato"'

1. Development status of a near-infrared integral field unit SWIMS-IFU

Author

Kosuke Kushibiki, Shinobu Ozaki, Masahiro Takeda, Takuya Hosobata, Yutaka Yamagata, Shinya Morita, Keiichi Nakagawa, Takao Saiki, Yutaka Ohtake, Toshihiro Tsuzuki, Kenji Mitsui, Hirofumi Okita, Kentaro Motohara, Hidenori Takahashi, Masahiro Konishi, Natsuko M. Kato, Shuhei Koyama, Nuo Chen, Shogo Homan, and Akino Yasuda

Published
2022

2. The University of Tokyo Atacama Observatory 6.5m telescope: Safety management at the extremely high Chajnantor site

Author

Hisaka Iwano, Takashi Miyata, Tomoki Morokuma, Masahiro Konishi, Yukihiko Hamamichi, Tsutomu Aoki, Yuzuru Yoshii, Takao Soyano, Hidenori Takahashi, Kotaro Kohno, Natsuko M. Kato, Mamoru Doi, Mizuki Numata, Osamu Mastubara, Kentaro Asano, Takeo Minezaki, Bunyo Hatsukade, Toshihiko Tanabe, Takafumi Kamizuka, Shigeyuki Sako, Masuo Tanaka, Joaquin Collao, Hiroaki Sameshima, and Ken'ichi Tarusawa

Subjects
Uv protection, business.product_category, Workload, Effects of high altitude on humans, law.invention, Telescope, Work (electrical), Aeronautics, Observatory, law, Internet access, Communications satellite, Environmental science, business
Abstract

Since the University of Tokyo Atacama Observatory (TAO) is located in extremely high altitude (5,640 m.a.s.l.), safety management is one of the most important issues for the project. We have developed safety management program for work at the site in order to prevent medical illness for humans. In this program all staff have to take medical examinations such as Electrocardiogram and Hipobaria before their work starts. The results are reviewed by medical doctor. Only authorized staff can be permitted to work at the site. During stay in site, all staff need to always use oxygen supply because there is only half of the oxygen at the site. It is also important to understand physical workload at the site. Our safety staff reviews it and determines necessary resting time for each worker, e.g. great load works need to work 50 minutes and rest 10 minutes. In addition to low air pressure, very low temperature, extremely high UV radiation, and extremely dry atmosphere should be concerned. Our program requests all staff to use winter clothes, sunblock and UV protection sunglasses and a lot of potable water consumption. Keep communication is also very important to secure the safety. Normal telephone communication is not available as well as internet connectivity. We have established satellite communication as well as UHF internal communication for general works and safety coordination with other observatories in Atacama area.

Published
2020

3. The University of Tokyo Atacama Observatory 6.5m Telescope: Design of mirror coating system and its performances II

Author

Yoshimitsu Kawai, Takao Soyano, Tomoki Morokuma, Natsuko M. Kato, Masahiro Konishi, Tsutomu Aoki, Takashi Miyata, Takafumi Kamizuka, Toshihiko Tanabe, Kentaro Motohara, Kotaro Kohno, Kentaro Asano, Shigeyuki Sako, Yuzuru Yoshii, Takeo Minezaki, Bunyo Hatsukade, Masuo Tanaka, Mizuki Numata, Hidenori Takahashi, Hiroshi Ogawa, Hiroaki Sameshima, Ken'ichi Tarusawa, and Mamoru Doi

Subjects
Materials science, business.industry, engineering.material, Ion bombardment, Stripping (fiber), law.invention, Primary mirror, Telescope, Optics, Coating, law, Observatory, Coating system, engineering, Vacuum level, business
Abstract

The telescope of the University of Tokyo Atacama Observatory has a primary mirror with a diameter in 6.5m. In order to fabricate the reflecting film initially on the mirror surface and to maintain its optical performance over a long period, a mirror{coating facility will be installed in operation building beside enclosure of the telescope at the summit of Co. Chajnantor (5,640m). The facility consists of mirror coating chamber, cleaning unit for stripping off the old film and clean-up the mirror, and a cart with a lifter for handling the primary mirror cell. Almost all equipment, including the main chamber, was completed by early 2020 and engaged as a mirror coating facility. In order to optimize the coating parameters, comprehensive performance tests were carried out (without primary mirror cell which plays a role of a part of chamber). The evaluation items are how long it takes to reach the target vacuum level and parameters of the current, voltage, and application time during ion bombardment and aluminization. Through iterating test, we were able to obtain each parameter that ultimately met the requirements of the TAO telescope mirror.

Published
2020

4. The University of Tokyo Atacama Observatory 6.5m telescope: site development

Author

Mizuki Mumata, Takashi Miyata, Hiroaki Sameshima, Tsutomu Aoki, Hisaka Iwano, Takao Soyano, Ken'ichi Tarusawa, Toshihiko Tanabe, Masuo Tanaka, Kotaro Kohno, Kentaro Motohara, Hidenori Takahashi, Takeo Minezaki, Osamu Matsubara, Yukihiko Hamamichi, Tomoki Morokuma, Bunyo Hatsukade, Yuzuru Yoshii, Joaquin Collao, Takafumi Kamizuka, Shigeyuki Sako, Natsuko M. Kato, and Mamoru Doi

Subjects
Limited access, Telescope, Summer season, geography, Altitude, Summit, geography.geographical_feature_category, Meteorology, law, Observatory, Foundation (engineering), Geology, law.invention
Abstract

One of remarkable features of the University of Tokyo Atacama Observatory (TAO) is an altitude of the site (5,640 m.a.s.l.) While this provides us an excellent condition for astronomical observations, the site development is attended with difficulty due to the hard conditions such as low pressure, low temperature, and limited access. Site preparation for the TAO 6.5 m telescope started in Apr. 2018. Firstly, we have constructed an access road from Pampa la bola plateau (~ 5,000 m.a.s.l) to the summit. It has a width of < 6.5 meter for transportation of telescope parts including the 6.5meter mirror. In order to prevent collapse, angle of side slope is carefully determined based on ground condition and frozen soils. All workers always use oxygen during their work as a measure against hypobaropathy. Since the site temperature in night is lower than 0 degree even in the summer season, it is difficult to ensure quality of foundation concrete if we cast it in-situ. We use pre-cast concrete for the foundation of the telescope, the enclosure, and the support building. The biggest part is the telescope foundation. It has a weight of 600 ton. Considering the transportation to the summit, it is divided into 43 parts and unified at the summit. This is a new trial to make a massive foundation for a large telescope with pre-cast concrete.

Published
2020

5. The University of Tokyo Atacama Observatory 6.5m telescope: update of the Near-Infrared Echelle Spectrograph NICE as the first light instrument

Author

Yuzuru Yoshii, Kentaro Asano, Takao Soyano, Mizuki Numata, Takashi Miyata, Hiroaki Sameshima, Ken'ichi Tarusawa, Mamoru Doi, Hidenori Takahashi, Toshihiko Tanabe, Kotaro Kohno, Takafumi Kamizuka, Shigeyuki Sako, Atsushi Nishimura, Tomoki Morokuma, Natsuko M. Kato, Bunyo Hatsukade, Kentaro Motohara, T. Aoki, Masuo Tanaka, Takeo Minezaki, Masahiro Konishi, and S. Koshida

Subjects
Physics, Wavelength range, Near-infrared spectroscopy, Infrared telescope, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, First light, law.invention, Telescope, law, Observatory, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Spectrograph, Astrophysics::Galaxy Astrophysics
Abstract

The Near-Infrared Cross-dispersed Echelle spectrograph (NICE) is a first light instrument for the TAO 6.5 m telescope. The instrument covers a wavelength range of 0.9 to 2.4 µm and has a resolving power of λ/∆λ ~2,600. NICE was first used on the 1.5 m infrared telescope at the National Astronomical Observatory of Japan from 2001 to 2005 and on the 1.6 m Pirka telescope in Japan from 2009 to 2018. We are now upgrading the cryogenics and computer system for the installation of NICE on the TAO telescope. Here we report on the current status and future schedules of instrumentation updates, control system, and modified specifications of NICE for its transfer to the TAO 6.5 m telescope.

Published
2020

6. The University of Tokyo Atacama Observatory 6.5m telescope: On-sky performance evaluations of the mid-infrared instrument MIMIZUKU on the Subaru telescope

Author

Tomoki Morokuma, Mamoru Doi, Takeo Minezaki, Masahiro Konishi, Hiroki Nakamura, Natsuko M. Kato, Takashi Miyata, Kosuke Kushibiki, Tsutomu Aoki, Ryou Ohsawa, S. Koshida, Kotaro Kohno, Mizuki Numata, Takashi Onaka, Takafumi Kamizuka, Itsuki Sakon, Kentaro Asano, Kengo Tachibana, Hirokazu Kataza, Hiroaki Sameshima, Yasunori Terao, Shigeyuki Sako, Ken'ichi Tarusawa, Yoichi Tamura, Takao Soyano, Yutaka Yoshida, Bunyo Hatsukade, Kentaro Motohara, Tsubasa Michifuji, Toshihiko Tanabe, Mizuho Uchiyama, Hidenori Takahashi, Yuzuru Yoshii, Tomohiro Mori, Masahito S. Uchiyama, and Masuo Tanaka

Subjects
Physics, media_common.quotation_subject, Astronomy, law.invention, Telescope, Wavelength, Sky, law, Observatory, Infrared window, Calibration, Subaru Telescope, Noise (radio), media_common
Abstract

The Mid-Infrared Multi-field Imager for gaZing at the UnKnown Universe (MIMIZUKU) is developed as the first-generation mid-infrared instrument for the University of Tokyo Atacama Observatory (TAO) 6.5-m telescope. MIMIZUKU performs medium-band imaging and low-resolution spectroscopy in 2-38 microns and enables highest-spatial-resolution observations in the long-wavelength mid-infrared beyond 25 microns. In addition, MIMIZUKU has a unique opto-mechanical device called ‘Field Stacker’, which enables us to observe a distant (

Published
2020

7. The University of Tokyo Atacama Observatory 6.5m telescope: Permafrost hazards and the high-altitude infrastructures

Author

Tomoki Morokuma, Mamoru Doi, Yuzuru Yoshii, Takeo Minezaki, Takashi Miyata, Gabriela Mena, Kotaro Kohno, Hidenori Takahashi, Takafumi Kamizuka, Kenji Yoshikawa, Norbert Schorghofer, Toshihiko Tanabe, Shigeyuki Sako, Kentaro Motohara, Masahiro Konishi, Hiroaki Sameshima, Natsuko M. Kato, Bunyo Hatsukade, Masuo Tanaka, Ken'ichi Tarusawa, Mizuki Numata, Tsutomu Aoki, and Takao Soyano

Subjects
geography, geography.geographical_feature_category, Frost weathering, Volcano, Observatory, Frost heaving, Environmental science, Weathering, Effects of high altitude on humans, Permafrost, Atmospheric sciences, Active layer
Abstract

Ice rich permafrost is observed at Chajnantor volcano (5,640m a.s.l.) on the University of Tokyo Atacama Observatory (TAO) site. Presence or absence of the permafrost is considered to be requested quite different engineering skills for their infrastructures. Lower altitude boundary is reported to be above 5,079m a.s.l. and maximum active (thawing) layer is 14cm. Minimal seasonal temperature variation, small active layer thickness as the consequences of low numbers of thawing and freezing degree days. Diurnal amplitude results in freeze-thaw cycles only near the surface. Severe frost shattering occurs near the ground surface, producing a dusty, fine-material horizon called a hyper-cryogenic layer. The importance of the snow-covered season for providing great protection for surface energy penetration. Many permafrost hazards are expecting in this construction site such as frost heaving, subsiding, mass movements, erosion, chemical weathering, frost shattering, embankment instability, and

Published
2020

8. Fabrication of mirror arrays with an ultra-precision cutting technique for a near-infrared integral field unit SWIMS-IFU

Author

Yasunori Terao, Masahiro Konishi, Toshihiro Tsuzuki, Yukihiro Kono, Kentaro Motohara, Hidenori Takahashi, Shinobu Ozaki, Takuya Hosobata, Shinya Morita, Yutaka Yamagata, Hiroki Nakamura, Natsuko M. Kato, Kosuke Kushibiki, and Masahiro Takeda

Subjects
Physics, Fabrication, Image quality, business.industry, Near-infrared spectroscopy, Curved mirror, law.invention, Telescope, Optics, law, Surface roughness, Pinhole (optics), business, Spectrograph
Abstract

We are developing an image-slicer type integral field unit (IFU), SWIMS-IFU, for SWIMS (Simultaneous-color Wide-field Infrared Multi-object Spectrograph), a near-infrared instrument for TAO 6.5 m telescope. SWIMS- IFU divides a field-of-view of 16:006 12:008 into 26 slices with a width of 0:005, which is the largest FoV among near-infrared IFUs on 8 m class telescopes. It is also capable of obtaining entire near-infrared spectra from 0.9 to 2.5 m with R1000 with a single exposure. Because of limitations of space in SWIMS, SWIMS-IFU should fit in a volume of 170 x 220 x 60 mm3, which results in small and complicatedly aligned mirror facets. To reduce alignment procedures, we adopt an ultra-precision cutting technique to fabricate mirror arrays monolithically. We have completed one of the mirror arrays, the slit-mirror array which consists of 26 spherical mirror facets, and confirmed both their surface roughness and shape errors satisfy the requirements. We also have fabricated a prototype of the pupil-mirror array including some elliptical mirror facets and confirmed that the elliptical mirrors have enough surface qualities and produce better image quality than spherical ones by a pinhole imaging test.

Published
2020

9. The University of Tokyo Atacama Observatory 6.5 m telescope: Development of the telescope and the control system

Author

Takao Soyano, Takafumi Kamizuka, Bunyo Hatsukade, Mitsufumi Nishimura, Yoshitaka Matsumoto, Kentaro Motohara, Tomoki Morokuma, Mamoru Doi, Takayuki Seki, Shigeyuki Sako, Masuo Tanaka, Shintaro Nakamaru, Kotaro Kohno, Masahiro Konishi, Natsuko M. Kato, Kentaro Asano, Tsutomu Aoki, Hidenori Takahashi, Takeo Minezaki, Hiroaki Sameshima, Naruyo Kajitani, Ken'ichi Tarusawa, T. Yoshikawa, Mizuki Numata, Takashi Miyata, Yuzuru Yoshii, Toshihiko Tanabe, and Yuji Ikeda

Subjects
Physics, business.industry, Stray light, Field of view, Active optics, law.invention, Telescope, Primary mirror, Optics, law, Observatory, Telescope mount, Secondary mirror, business
Abstract

The University of Tokyo Atacama Observatory Project is to construct a 6.5 m infrared-optimized telescope at the summit of Co. Chajnantor (5640 m altitude) in northern Chile. The telescope optics uses a Ritchey-Chretien type layout, with an under-sized secondary mirror to reduce stray light caused by thermal emission from the telescope structure. The primary mirror is a F/1.25 lightweight borosilicate glass (Ohara E6) mirror with honeycomb structure, which is developed by Steward Observatory Richard F. Caris Mirror Lab. The telescope has two Nasmyth foci and two folded-Cassegrain foci, which can be switched by rotating a tertiary mirror. The final focal ratio is 12.2 with a field of view of 25 arcmin in diameter. The telescope mount is a tripod-disk alt-azimuth mount. Both the azimuth and elevation axes are supported by and run on hydrostatic bearings, and they are driven by friction drives with servo motors, which are controlled by the telescope control system. It also controls the hexapod mount of the secondary mirror and the pneumatic actuators of the primary mirror support to keep good image quality during the observation. An off-axis Shack-Hartmann sensor installed in each focus measures the wavefront aberration of the telescope optics, then the misalignment between the secondary and primary mirrors is corrected by adjusting the hexapod mount while other aberrations are corrected by the deformation of the primary mirror. The force distribution of the actuators for correction will be calculated by fitting the wave-front errors with a series of bending modes of the primary mirror.

Published
2020

10. Design of an integral field unit for SWIMS and its milling process fabrication with an ultra-high precision machine tool

Author

Yasunori Terao, Hirofumi Ohashi, Toshihiro Tsuzuki, Natsuko M. Kato, Yutaka Yamagata, Kentaro Motohara, Hidenori Takahashi, Kosuke Kushibiki, Yukihiro Kono, Shinobu Ozaki, Yutaro Kitagawa, Masahiro Konishi, and Shinya Morita

Subjects
Materials science, Vignetting, business.product_category, Fabrication, Tolerance analysis, business.industry, law.invention, Machine tool, Telescope, Optics, law, Surface roughness, Wafer, business, Spectrograph
Abstract

SWIMS-IFU is an image-slicer integral field unit designed for Simultaneous-color Wide-field Infrared Multi-object Spectrograph (SWIMS) of the University of Tokyo Atacama observatory 6.5m telescope. Its field-of-view, slice width and slice number are 17.2 ′′ × 12.8 ′′, 0.4 ′′ and 26, respectively. Due to the space limitation inside SWIMS, the IFU should fit in the dimension of 60mm×170mm×220mm. After finishing development of optical design, we have conducted tolerance analysis. The results show that the probability of vignetting of less than 5% is ∼90%, although at a slice of one side it drops to 50%. We plan to fabricate the mirror arrays monolithically by a ball-end milling with an ultra-high precision machine tool, and have conducted a demonstration process to prove its feasibility. Our requirement for shape error is less than 100 nm P-V and that for surface roughness is less than 10 nm r.m.s. Results of the latest demonstration satisfies the requirement. We will fabricate the mirror arrays and the support structures in 2018, and the IFU will be installed into SWIMS in 2019.

Published
2018

11. NIR camera and spectrograph SWIMS for TAO 6.5m telescope: overview and development status

Author

Mizhuo Uchiyama, Masahiro Konishi, Tomoki Morokuma, Ryou Ohsawa, Yuzuru Yoshii, Tsutomu Aoki, Masuo Tanaka, Takafumi Kamizuka, Hidenori Takahashi, Masahito S. Uchiyama, Takao Soyano, S. Koshida, Hirofumi Ohashi, Kotaro Kohno, Ken'ichi Tarusawa, Shigeyuki Sako, Kiyoshi Mori, Mamoru Doi, Yutaka Kobayakawa, Takeo Minezaki, Natsuko M. Kato, Yoichi Tamura, Ken Tateuchi, Soya Todo, Yutaro Kitagawa, Kazushi Okada, Toshihiko Tanabe, Takashi Miyata, Yasunori Terao, Kentaro Motohara, and Kentaro Asano

Subjects
Physics, business.industry, Near-infrared spectroscopy, Field of view, 01 natural sciences, Collimated light, law.invention, 010309 optics, Telescope, Optics, Observatory, law, Infrared window, 0103 physical sciences, Dichroic filter, business, 010303 astronomy & astrophysics, Spectrograph, Remote sensing
Abstract

Simultaneous-color Wide-field Infrared Multi-object Spectrograph, SWIMS, is one of the first generation instruments for University of Tokyo Atacama Observatory 6.5m Telescope where almost continuous atmospheric window from 0.9 to 2.5μm appears, thanks to the high altitude and dry climate of the site. To utilize this excellent condition, SWIMS is capable of simultaneous two-color imaging with a field of view of 9’. in diameter and λ/Δλ ~1000 multi-object spectroscopy at 0.9–2.5μm in a single exposure, utilizing a dichroic mirror inserted in the collimated beam. Here, we overview the instrument, report results of its full-assembly tests in the laboratory and present the future plan.

Published
2016

12. Development status of the mid-infrared two-field camera and spectrograph MIMIZUKU for the TAO 6.5-m Telescope

Author

Kentaro Asano, Yutaro Kitagawa, Jumpei Yamaguchi, Hidenori Takahashi, Tomoki Morokuma, Kiyoshi Mori, Masahito S. Uchiyama, Yasunori Terao, Yoichi Tamura, Takeo Minezaki, Mizuho Uchiyama, Yutaka Kobayakawa, Itsuki Sakon, Natsuko M. Kato, Ryou Ohsawa, Hirokazu Kataza, Naruhisa Takato, Kentaro Motohara, Fumihiko Usui, Yuzuru Yoshii, Mamoru Doi, Takashi Onaka, Masahiro Konishi, Takafumi Kamizuka, Tsutomu Aoki, Shigeyuki Sako, Kotaro Kohno, Masuo Tanaka, Takashi Miyata, Toshihiko Tanabe, Hirofumi Ohashi, Ken'ichi Tarusawa, Sunao Hasegawa, Takao Soyano, and Kazushi Okada

Subjects
Physics, Infrared, business.industry, Detector, Cryogenics, 01 natural sciences, law.invention, 010309 optics, Telescope, Optics, Observatory, law, 0103 physical sciences, business, Subaru Telescope, Spectroscopy, 010303 astronomy & astrophysics, Spectrograph
Abstract

MIMIZUKU is the first-generation mid-infrared instrument for the university of Tokyo Atacama Observatory (TAO) 6.5-m telescope. MIMIZUKU provides imaging and spectroscopic monitoring capabilities in a wide wavelength range from 2 to 38 μm, including unique bands like 2.7-μm and 30-μm band. Recently, we decided to add spectroscopic functions, KL-band mode (λ= 2.1-4.0 μm; R =λ/Δλ ~ 210) and 2.7-μm band mode ( λ= 2.4-2.95 μm; R ~ 620), and continuous spectroscopic coverage from 2.1 to 26 μm is realized by this update. Their optical designing is completed, and fabrications of optical elements are ongoing. As recent progress, we also report the completion of the cryogenic system and optics. The cryogenic system has been updated by changing materials and structures of thermal links, and the temperatures of the optical bench and detector mounting stages finally achieved required temperatures. Their stability against instrument attitude is also confirmed through an inclination test. As for the optics, its gold-plated mirrors have been recovered from galvanic corrosion by refabrication and reconstruction. Enough image quality and stability are confirmed by room-temperature tests. MIMIZUKU is intended to be completed in this autumn, and commissioning at the Subaru telescope and scientific operations on the TAO telescope are planned in 2017 and around 2019, respectively. In this paper, these development activities and future prospects of MIMIZUKU are reported.

Published
2016

13. NIR camera and spectrograph SWIMS for TAO 6.5m telescope: array control system and its performance

Author

Hirofumi Ohashi, Soya Todo, Ken Tateuchi, Hidenori Takahashi, Yutaro Kitagawa, Masahiro Konishi, Yasunori Terao, Yutaka Kobayakawa, Kentaro Motohara, and Natsuko M. Kato

Subjects
business.industry, Infrared, Computer science, Detector, 01 natural sciences, law.invention, 010309 optics, Telescope, Noise, Cardinal point, Software, Observatory, law, Embedded system, Control system, 0103 physical sciences, business, 010303 astronomy & astrophysics, Spectrograph, Computer hardware
Abstract

SWIMS (Simultaneous-color Wide- eld Infrared Multi-object Spectrograph) is a near-infrared imager and multi-object spectrograph as one of the rst generation instruments for the University of Tokyo Atacama Observatory(TAO) 6.5m telescope. In this paper, we describe an array control system of SWIMS and results of detectornoise performance evaluation. SWIMS incorporates four (and eight in future) HAWAII-2RG focal plane arraysfor detectors, each driven by readout electronics components: a SIDECAR ASIC and a JADE2 Card. Thereadout components are controlled by a HAWAII-2RG Testing Software running on a virtual Windows machineon a Linux PC called array control PC. All of those array control PCs are then supervised by a SWIMS controlPC. We have developed an \array control software system", which runs on the array control PC to control theHAWAII-2RG Testing Software, and consists of a socket client and a dedicated server called device manager.The client runs on the SWIMS control PC, and the device manager runs on the array control PC. An exposurecommand, issued by the client on the SWIMS control PC, is sent to the multiple device managers on the arraycontrol PCs, and then multiple HAWAII-2RGs are driven simultaneously. Using this system, we evaluate readoutnoise performances of the detectors, both in a test dewar and in a SWIMS main dewar. In the test dewar, wecon rm the readout noise to be 4.3 e r.m.s. by 32 times multiple sampling when we operate only a singleHAWAII-2RG, whereas in the case of simultaneous driving of two HAWAII-2RGs, we still obtain su ciently lowreadout noise of 10 e r.m.s.. In the SWIMS main dewar, although there are some di erences between thedetectors, the readout noise is measured to be 4 :1{4 :6 e r.m.s. with simultaneous driving by 64 times multiplesampling, which meets the requirement for background-limited observations in J band of 14 e r.m.s..Keywords: HAWAII-2RG, SWIMS, near-infrared, TAO

Published
2016

14. Fabrication of a wide-field NIR integral field unit for SWIMS using ultra-precision cutting

Author

Hidenori Takahashi, Shinobu Ozaki, Yutaka Yamagata, Yasunori Terao, Yutaka Kobayakawa, Natsuko M. Kato, Shinya Morita, Yutaro Kitagawa, Kentaro Motohara, Masahiro Konishi, and Hirofumi Ohashi

Subjects
Fabrication, Materials science, business.industry, Near-infrared spectroscopy, Process (computing), 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, law.invention, 010309 optics, Telescope, Optics, law, Observatory, 0103 physical sciences, Surface roughness, Ideal surface, 0210 nano-technology, business, Spectrograph
Abstract

We describe overview of fabrication methods and measurement results of test fabrications of optical surfaces for an integral field unit (IFU) for Simultaneous color Wide-field Infrared Multi-object Spectrograph, SWIMS, which is a first-generation instrument for the University of Tokyo Atacama Observatory 6.5-m telescope. SWIMS-IFU provides entire near-infrared spectrum from 0.9 to 2.5 μm simultaneously covering wider field of view of 17" × 13" compared with current near-infrared IFUs. We investigate an ultra-precision cutting technique to monolithically fabricate optical surfaces of IFU optics such as an image slicer. Using 4- or 5-axis ultra precision machine we compare the milling process and shaper cutting process to find the best way of fabrication of image slicers. The measurement results show that the surface roughness almost satisfies our requirement in both of two methods. Moreover, we also obtain ideal surface form in the shaper cutting process. This method will be adopted to other mirror arrays (i.e. pupil mirror and slit mirror, and such monolithic fabrications will also help us to considerably reduce alignment procedure of each optical elements.

Published
2016

16. Development of a simultaneous two-color near-infrared multi-object spectrograph SWIMS for the TAO 6.5-m telescope

Author

Shintaro Koshida, Tomoki Morokuma, Kazushi Okada, Ken'ichi Tarusawa, Ryou Ohsawa, Yutaro Kitagawa, Takeo Minezaki, Takashi Miyata, Yuzuru Yoshii, Mamoru Doi, Ken Tateuchi, Toshihiko Tanabe, Natsuko M. Kato, Hidenori Takahashi, Mizuho Uchiyama, Kotaro Kohno, Masuo Tanaka, Takao Soyano, Kentaro Motohara, Kentaro Asano, Takafumi Kamizuka, Yoichi Tamura, Kimiaki Kawara, Soya Todo, Shigeyuki Sako, Masahiro Konishi, and Tsutomu Aoki

Subjects
Physics, Galactic astronomy, Reflecting telescope, business.industry, Astronomy, law.invention, Telescope, Primary mirror, Optics, law, Observatory, Infrared window, business, Subaru Telescope, Spectrograph
Abstract

The Simultaneous-color Wide-field Infrared Multi-object Spectrograph, SWIMS, is a first-generation near-infrared instrument for the University of Tokyo Atacama Observatory (TAO) 6.5m Telescope now being constructed in northern Chile. To utilize the advantage of the site that almost continuous atmospheric window appears from 0.9 to 2.5 μm, the instrument is capable of simultaneous two-color imaging with a field-of-view of 9.′6 in diameter or λ/uλ 1000 multi-object spectroscopy at 0.9–2.5 μm in a single exposure. The instrument has been trans- ported in 2017 to the Subaru Telescope as a PI-type instrument for carrying out commissioning observations before starting science operation on the 6.5m telescope. In this paper, we report the latest updates on the instrument and present preliminary results from the on-sky performance verification observations.

Published
2014

17. Optimization and performance of H2RG detectors and SIDECAR ASICs for SWIMS

Author

Ken Tateuchi, Yutaro Kitagawa, Soya Todo, Hidenori Takahashi, Natsuko M. Kato, Kentaro Motohara, and Masahiro Konishi

Subjects
Physics, Correlated double sampling, Physics::Instrumentation and Detectors, business.industry, Preamplifier, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Noise (electronics), chemistry.chemical_compound, Optics, Application-specific integrated circuit, chemistry, Sampling (signal processing), Mercury cadmium telluride, business, Spectrograph
Abstract

SWIMS (Simultaneous-color Wide-field Infrared Multi-object Spectrograph) is one of the first-generation instru- ments for the University of Tokyo Atacama Observatory 6.5-m telescope which is now under construction in northern Chile. This instrument incorporates 4 (and maximum 8 in future) HgCdTe HAWAII-2RG detectors, from which images are acquired by SIDECAR ASICs. Characterization and validation of performances of these detectors are carried out using a test dewar at 80K using liquid nitrogen. Bias voltages such as reset level and substrate level and reference voltages are optimized to minimize readout noise with keeping output levels within proper range for ADC inputs. ADU-electron conversion gain gc is measured by photon-transfer method, incorporating IPC (Inter-Pixel Capacitance) correction. IPC coefficient is measured to be about 1.4%, which result in overestimation of gc by about 13%. After this correction, gc is measured to be about 2:4 e-=ADU with normal preamplifier gain setting in the ASICs. Correlated double sampling (CDS) readout noise is about 16 e- rms, and is reduced to about 4 e- rms by Multi Fowler sampling. The noise is different by 30% at most between channels of the ASIC. We also separate noise sources into those come from detector pixels, from a at cable between the detector and the ASIC, and from preamps and from ADCs, and found that the detector pixels are the major sources of readout noise. Fitting of linearity curve is also obtained. The next step is to study the effects of driving multiple detectors to the performances and to install the detectors into SWIMS.

Published
2014

18. Design of mirror coating facility for The University of Tokyo Atacama Observatory 6.5m telescope

Author

Mamoru Doi, Yuzuru Yoshii, Toshihiro Handa, Hidenori Takahashi, Masuo Tanaka, Tomoki Morokuma, Masahiro Konishi, Takeo Minezaki, Tsutomu Aoki, Kimiaki Kawara, Kentaro Motohara, Toshihiro Tanabé, Yoishi Tamura, Ken'ichi Tarusawa, Takafumi Kamizuka, Takashi Miyata, Kotaro Kohno, Shigeyuki Sako, Natsuko M. Kato, Takao Soyano, and Shintaro Koshida

Subjects
Fabrication, Materials science, business.industry, Infrared telescope, engineering.material, Stripping (fiber), law.invention, Primary mirror, Telescope, Optics, Coating, Observatory, law, engineering, Vacuum chamber, business
Abstract

The telescope of the University of Tokyo Atacama Observatory has a 6.5-m primary mirror in diameter. In order to fabricate the reflecting film initially and to maintain its performance over a long period, we have mirror coating facility on site. We have chosen to leave the primary mirror in its cell with the mirror support system intact. Two major advantages of leaving the mirror in its cell are that the mirror does not have to be lifted or handled and the support system does not have to be removed or reinstalled for coating. The facility consists of a clean booth for stripping of the old film, an evaporation coating chamber, and a cart with a lifter for handling the primary mirror. A conventional evaporation system with a metal pre-wetted filament array is adopted for achieving various optical requests. The coating equipment has also a function of fabrication for film on secondary and tertiary mirrors.

Published
2014

19. Revised specifications and current development status of MIMIZUKU: the mid-infrared instrument for the TAO 6.5-m telescope

Author

Itsuki Sakon, Yutaro Kitagawa, Kentaro Asano, Kentaro Motohara, Shintaro Koshida, Natsuko M. Kato, Hidenori Takahashi, Tomohiko Nakamura, Mamoru Doi, Ryou Ohsawa, Takafumi Kamizuka, Kimiaki Kawara, Kotaro Kohno, Takashi Onaka, Yuzuru Yoshii, Shigeyuki Sako, Masuo Tanaka, Soya Todo, Kazushi Okada, Takeo Minezaki, Tomoki Morokuma, Takashi Miyata, Ken'ichi Tarusawa, Masahiro Konishi, Masahito S. Uchiyama, Ken Tateuchi, Hirokazu Kataza, Tsutomu Aoki, Mizuho Uchiyama, Toshihiko Tanabe, Takao Soyano, and Yoichi Tamura

Subjects
Cryostat, Physics, business.industry, Stacker, Detector, Near-infrared spectroscopy, Field of view, law.invention, Telescope, Optics, law, Calibration, Sensitivity (control systems), business, Remote sensing
Abstract

The MIMIZUKU is the first-generation mid-infrared instrument for the TAO 6.5-m telescope. It challenges to prove the origin of dust and the formation of planets with its unique capabilities, wide wavelength coverage and precise calibration capability. The wide wavelength coverage (2-38 μm) is achieved by three switchable cameras, NIR, MIR-S, and MIR-L. The specifications of the cameras are revised. A 5μm-cutoff HAWAII-1RG is decided to be installed in the NIR camera. The optical design of the MIR-L camera is modified to avoid detector saturation. Its final F-number is extended from 5.2 to 10.5. With these modifications, the field of view of the NIR and MIR-L camera becomes 1.2’ × 1.2’ and 31” × 31”, respectively. The sensitivity of each camera is estimated based on the revised specifications. The precise calibration is achieved by the “Field Stacker” mechanism, which enables the simultaneous observation of the target and the calibration object in different fields. The up-and-down motion of the cryostat (~ 1 t), critical for the Field Stacker, is confirmed to have enough speed (4 mm/s) and position accuracy (~ 50 μm). A control panel for the Field Stacker is completed, and its controllers are successfully installed. The current specifications and the development status are reported.

Published
2014

20. Development of multi-object spectroscopy unit for simultaneous-color wide-field infrared multi-object spectrograph

Author

Natsuko M. Kato, Ken Tateuchi, Yurato Kitagawa, Kentaro Motohara, Soya Todo, Masahiro Konishi, and Hidenori Takahashi

Subjects
Physics, business.industry, Infrared, Function (mathematics), law.invention, Telescope, Optics, Cardinal point, law, Development (differential geometry), Spectroscopy, business, Spectrograph, Robotic arm
Abstract

SWIMS (Simultaneous-color Wide-field Infrared Multi-object Spectrograph) has a multi-object spectroscopic function including IFU in addition to the imaging capability. The mechanism in order to achieve this function is Multi-Object Spectroscopy Unit. This is the function that can derive spectra of simultaneous 20–30 objects over range from 0.9 to 2.5μmm. To set or exchange a slit mask on telescope focal plane, MOSU consists of the slit-mask dewar (carrousel), focal plane dewar, and robotic arm called mask catcher. There are many structural and mechanical features in MOSU to achieve its performance in cooling system, positional repeatability of slit mask and so on. We present here its unique components and its specifications and performance.

Published
2014

21. Evaluations of new atmospheric windows at thirty micron wavelengths for astronomy

Author

Mizuki Yoneda, Yuzuru Yoshii, Takeo Minezaki, Hidenori Takahashi, Takashi Miyata, Takao Soyano, Kentaro Asano, Tomoki Morokuma, Toshihiko Tanabe, Mamoru Doi, Kotaro Kohno, Mizuho Uchiyama, Shintaro Koshida, Tomohiko Nakamura, Masuo Tanaka, Yoichi Tamura, Naruhisa Takato, Masahiro Konishi, Tsutomu Aoki, Takafumi Kamizuka, Shigeyuki Sako, Natsuko M. Kato, Kimiaki Kawara, Kentaro Motohara, and Ken'ichi Tarusawa

Subjects
Physics, Daytime, business.industry, media_common.quotation_subject, Night sky, Astronomy, law.invention, Telescope, Wavelength, Optics, Observational astronomy, Sky, law, Infrared window, Transmittance, business, media_common
Abstract

Thirty micron has remained one of unexplored frontiers of ground-based astronomical observations. Recent developments of extreme high sites including the Chajnantor TAO site (5,640m) enable us to access the this wavelengths from the ground. The expected transmittance seems clear enough for astronomical observations, but practical evaluations based on astronomical data has not been carried out yet. We have analyzed images obtained at the 31.7 micron with a mid-infrared camera MAX38 attached on a mini-TAO 1.0-meter telescope. 109 images of a star IRC+10420 and 11,114 images of the sky have been reduced. Clear relationship between the measured photocurrents and the perceptible water vapor has been found. Simple estimation of the photocurrents with of the ATRAN model gives good agreements with the measurements, indicating that the ATRAN model reproduce the atmospheric transmittance reasonably well. This also supports our assumption that the scaling factor 0.85 of the PVW at the Chajnantor TAO site to the PWV at the APEX. The average transmittance in the 31.7 micron is achieved to be over 20% when the PWV below 0.6 mm. In some cases clear degradation up to 10% in the transmittance is found. It may be caused by droplets of liquid or iced water with a size over 10 micron although the causes are not exactly specified. Diurnal time variations of the sky photocurrents are also investigated. The sky is sometimes bright and usually unstable in the twilight time. On the other hand the sky around the noontime does not show clear difference from the night sky. It may suggest that the observing condition at the thirty micron windows remain good even in the daytime.

Published
2012

Catalog

Books, media, physical & digital resources
See catalog results