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2. Sputtered anti-reflection layer on transparent polyimide substrate improves adhesion strength to copper layer: effects of layer thickness and sputtering power

Author

Yuan-Nan Tsai, Shih-Chieh Chin, Hsin-Yo Chen, Ta-I. Yang, Mei-Hui Tsai, and I.-Hsiang Tseng

Subjects
General Chemical Engineering, General Chemistry
Abstract

In order to shield the electronic circuits on a transparent polyimide (PI) substrate, an anti-reflection (AR) layer was deposited on a PI film via DC reactive magnetron sputtering.

Published
2023

3. Prime focus spectrograph (PFS) for the Subaru Telescope: fiber optical cable and connector system (FOCCoS) – Integration

Author

Antonio Cesar de Oliveira, Ligia S. de Oliveira, Décio Ferreira, Lucas S. Marrara, Leandro H. dos Santos, Josimar A. Rosa, Rodrigo P. de Almeida, Ricardo L. da Costa, James E. Gunn, Yuki Moritani, Naoyuki Tamura, Naruhisa Takato, Laerte . Sodré, Graham Murray, David Le Mignant, Fabrice Madec, Kjetil Dohlen, Shiang-Yu Wang, Masahiko Kimura, Yin-Chang Chang, Hsin-Yo Chen, Daniel Reiley, Mitsko Roberts, and Brent Belland

Published
2022

5. Prime Focus Spectrograph (PFS) for the Subaru Telescope: its start of the last development phase

Author

Naoyuki Tamura, Yuki Moritani, Kiyoto Yabe, Yuki Ishizuka, Yukiko Kamata, Ali Allaoui, Akira Arai, Stéphane Arnouts, Robert H. Barkhouser, Rudy Barette, Patrick Blanchard, Eddie Bergeron, Neven Caplar, Pierre-Yves Chabaud, Yin-Chang Chang, Hsin-Yo Chen, Chueh-Yi Chou, You-Hua Chu, Judith G. Cohen, Ricardo L. da Costa, Thibaut Crauchet, Rodrigo P. de Almeida, Antonio Cesar . de Oliveira, Ligia S. de Oliveira, Kjetil Dohlen, Leandro H. dos Santos, Richard S. Ellis, Maximilian Fabricius, Décio Ferreira, Hisanori Furusawa, Jahmour J. Givans, Javier Garciá-Carpio, Mirek Golebiowski, Aidan C. Gray, James E. Gunn, Satoshi Hamano, Randolph P. Hammond, Albert Harding, Kota Hayashi, Wanqiu He, Timothy M. Heckman, Stephen C. Hope, Shu-Fu Hsu, Yen-Shan Hu, Pin Jie Huang, Miho N. Ishigaki, Eric Jeschke, Yipeng Jing, Erin Kado-Fong, Jennifer L. Karr, Satoshi Kawanomoto, Masahiko Kimura, Michitaro Koike, Eiichiro Komatsu, Shintaro Koshida, Vincent Le Brun, Arnaud Le Fur, David Le Mignant, Romain Lhoussaine, Yen-Ting Lin, Hung-Hsu Ling, Craig P. Loomis, Robert . Lupton, Fabrice Madec, Danilo Marchesini, Edouard Marguerite, Lucas S. Marrara, Dmitry Medvedev, Sogo Mineo, Satoshi Miyazaki, Takahiro Morishima, Kazumi Murata, Hitoshi Murayama, Graham J. Murray, Hirofumi Okita, Masato Onodera, Joshua P. Peebles, Paul Price, Tae-Soo Pyo, Lucio Ramos, Daniel J. Reiley, Martin Reinecke, Mitsuko K. Roberts, Josimar A. Rosa, Julien . Rousselle, Mira Sarkis, Michael D. Seiffert, Kiaina Schubert, Hassan Siddiqui, Stephen A. Smee, Laerte Sodré, Michael A. Strauss, Christian Surace, Manuchehr Taghizadeh Popp, Philip J. Tait, Masahiro Takada, Yuhei Takagi, Masayuki Tanaka, Yoko Tanaka, Aniruddha R. Thakar, Didier Vibert, Shiang-Yu Wang, Chih-Yi Wen, Suzanne Werner, Matthew Wung, Gerald Lemson, Arik Mitschang, Naoki Yasuda, Hiroshige Yoshida, Chi-Hung Yan, Michitoshi Yoshida, Takuji Yamashita, Laboratoire d'Astrophysique de Marseille (LAM), and Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[SDU]Sciences of the Universe [physics]
Abstract

International audience; PFS (Prime Focus Spectrograph), a next generation facility instrument on the Subaru telescope, is now being tested on the telescope. The instrument is equipped with very wide (1.3 degrees in diameter) field of view on the Subaru's prime focus, high multiplexity by 2394 reconfigurable fibers, and wide waveband spectrograph that covers from 380nm to 1260nm simultaneously in one exposure. Currently engineering observations are ongoing with Prime Focus Instrument (PFI), Metrology Camera System (MCS), the first spectrpgraph module (SM1) with visible cameras and the first fiber cable providing optical link between PFI and SM1. Among the rest of the hardware, the second fiber cable has been already installed on the telescope and in the dome building since April 2022, and the two others were also delivered in June 2022. The integration and test of next SMs including near-infrared cameras are ongoing for timely deliveries. The progress in the software development is also worth noting. The instrument control software delivered with the subsystems is being well integrated with its system-level layer, the telescope system, observation planning software and associated databases. The data reduction pipelines are also rapidly progressing especially since sky spectra started being taken in early 2021 using Subaru Nigh Sky Spectrograph (SuNSS), and more recently using PFI during the engineering observations. In parallel to these instrumentation activities, the PFS science team in the collaboration is timely formulating a plan of large-sky survey observation to be proposed and conducted as a Subaru Strategic Program (SSP) from 2024. In this article, we report these recent progresses, ongoing developments and future perspectives of the PFS instrumentation.

Published
2022

6. Prime focus spectrograph (PFS) for the Subaru Telescope: the prime focus instrument

Author

Shiang-Yu Wang, Masahiko Kimura, Chi-Hung Yan, Yin-Chang Chang, Shu-Fu Hsu, Jennifer L. Karr, Hsin-Yo Chen, Pin-Jie Huang, Chih-Yi Wen, Chueh-Yi Chou, Hung-Hsu Ling, Naoyuki Tamura, Yuki Moritani, Julien Rousselle, Hiroshige Yoshida, Shintaro Koshida, Naruhisa Takato, Dan J. Reiley, Mitsuko Roberts, James E. Gunn, Craig P. Loomis, Robert . Lupton, Neven Caplar, Hassan Siddiqui, Décio Ferreira, Leandro H. dos Santos, Ligia S. de Oliveira, Antonio Cesar de Oliveira, Lucas Souza Marrara, Maximilian Fabricius, and Graham J. Murray

Published
2022

7. Prime Focus Spectrograph (PFS) for the Subaru telescope: a next-generation facility instrument of the Subaru telescope has started coming

Author

Albert Harding, Yuki Okura, Lucio Ramos, Masahiro Takada, Satoshi Takita, Yuki Moritani, Masahiko Kimura, Michitoshi Yoshida, Aidan Gray, Judith G. Cohen, Michael A. Strauss, Richard S. Ellis, Mohamed Belhadi, Alain Schmitt, Josimar A. Rosa, Naoki Yasuda, Daniel J. Reiley, Hassan Siddiqui, Tomonori Tamura, Martin Reinecke, Yipeng Jing, David Le Mignant, Ricardo Costa, Leandro Henrique dos Santos, You-Hua Chu, Yen Shan Hu, Ligia Souza de Oliveira, Naruhisa Takato, Yoshihiko Yamada, Manuchehr Taghizadeh Popp, Youichi Ohyama, Michitaro Koike, Kjetil Dohlen, Yoko Tanaka, Pierre Yves Chabaud, Christian Surace, Takuji Yamashita, Murdock Hart, Olivier Le Fèvre, Kiyoto Yabe, James E. Gunn, Hisanori Furusawa, Antonio Cesar de Oliveira, Arnaud Le Fur, Robert H. Lupton, Hitoshi Murayama, Yukiko Kamata, Michael A. Carr, Yin Chang Chang, Robert H. Barkhouser, Shiang-Yu Wang, F. Madec, Graham J. Murray, Erin Kado-Fong, Philippe Balard, Satoshi Kawanomoto, Rudy Barette, Jill Burnham, Masato Onodera, Randolph Hammond, Naoyuki Tamura, Michael Seiffert, Aniruddha R. Thakar, Vincent Le Brun, Timothy M. Heckman, Chih Yi Wen, Thibaut Crahchet, D. Vibert, Julien Rousselle, Mira Sarkis, Mitsuko Roberts, Jennifer L. Karr, Stephen C. Hope, M. Golebiowski, Yuki Ishizuka, Edouard Marguerite, Chueh Yi Chou, Hirofumi Okita, Masayuki Tanaka, Joe D. Orndorff, Eric Jeschke, Kiaina Schubert, Stephen A. Smee, Joshua Peebles, Hsin Yo Chen, Craig P. Loomis, Ali Allaoui, Sogo Mineo, Décio Ferreira, Eiichiro Komatsu, Rodrigo P. de Almeida, Chi-Hung Yan, Matthew Wung, Javier Garcia-Carpio, Sandrine Pascal, Stéphane Arnouts, Danilo Marchesini, Philip J. Tait, Laerte Sodré, S. Koshida, Suzanne Werner, Lucas Souza Marrara, Ping Jie Huang, Dmitry Medvedev, Hung Hsu Ling, Maximilian Fabricius, Neven Caplar, Shu Fu Hsu, Hiroshige Yoshida, and M. Jaquet

Subjects
Optical fiber cable, Focus (computing), Engineering, business.industry, Field of view, law.invention, Software, Observatory, law, Systems engineering, Instrumentation (computer programming), business, Subaru Telescope, Spectrograph
Abstract

PFS (Prime Focus Spectrograph), a next generation facility instrument on the Subaru telescope, is a very wide- field, massively multiplexed, and optical and near-infrared spectrograph. Exploiting the Subaru prime focus, 2394 reconfigurable fibers will be distributed in the 1.3 degree-diameter field of view. The spectrograph system has been designed with 3 arms of blue, red, and near-infrared cameras to simultaneously deliver spectra from 380nm to 1260nm in one exposure. The instrumentation has been conducted by the international collaboration managed by the project office hosted by Kavli IPMU. The team is actively integrating and testing the hardware and software of the subsystems some of which such as Metrology Camera System, the first Spectrograph Module, and the first on-telescope fiber cable have been delivered to the Subaru telescope observatory at the summit of Maunakea since 2018. The development is progressing in order to start on-sky engineering observation in 2021, and science operation in 2023. In parallel, the collaboration is trying to timely develop a plan of large-sky survey observation to be proposed and conducted in the framework of Subaru Strategic Program (SSP). This article gives an overview of the recent progress, current status and future perspectives of the instrumentation and scientific operation.

Published
2021

8. Presynaptic SNAP-25 regulates retinal waves and retinogeniculate projection via phosphorylation

Author

Juu-Chin Lu, Ning Chiang, Tzu-Lin Cheng, Shih-Yuan Liou, Chih-Tien Wang, Sheng-Ping Hsu, Lam-Yan Cheung, Chien-Ting Huang, Yu-Chun Lin, Yu-Tien Hsiao, Cheng-Chang Yang, Hui-Ju Yang, Pin-Chun Chen, Yi-Ting Huang, Wen-Chi Shu, Ni-Yen Yu, Yen-Ju Chen, and Hsin-Yo Chen

Subjects
Retinal Ganglion Cells, Patch-Clamp Techniques, Synaptosomal-Associated Protein 25, Postsynaptic Current, Action Potentials, Embryonic Development, Endogeny, Retinal ganglion, Retina, chemistry.chemical_compound, Animals, Visual Pathways, Calcium Signaling, Phosphorylation, Gene knockdown, Multidisciplinary, Chemistry, Snap, Gene Expression Regulation, Developmental, Retinal, Synaptic Potentials, Biological Sciences, Retinal waves, Cell biology, Amacrine Cells, Animals, Newborn, Protein Binding
Abstract

Patterned spontaneous activity periodically displays in developing retinas termed retinal waves, essential for visual circuit refinement. In neonatal rodents, retinal waves initiate in starburst amacrine cells (SACs), propagating across retinal ganglion cells (RGCs), further through visual centers. Although these waves are shown temporally synchronized with transiently high PKA activity, the downstream PKA target important for regulating the transmission from SACs remains unidentified. A t-SNARE, synaptosome-associated protein of 25 kDa (SNAP-25/SN25), serves as a PKA substrate, implying a potential role of SN25 in regulating retinal development. Here, we examined whether SN25 in SACs could regulate wave properties and retinogeniculate projection during development. In developing SACs, overexpression of wild-type SN25b, but not the PKA-phosphodeficient mutant (SN25b-T138A), decreased the frequency and spatial correlation of wave-associated calcium transients. Overexpressing SN25b, but not SN25b-T138A, in SACs dampened spontaneous, wave-associated, postsynaptic currents in RGCs and decreased the SAC release upon augmenting the cAMP-PKA signaling. These results suggest that SN25b overexpression may inhibit the strength of transmission from SACs via PKA-mediated phosphorylation at T138. Moreover, knockdown of endogenous SN25b increased the frequency of wave-associated calcium transients, supporting the role of SN25 in restraining wave periodicity. Finally, the eye-specific segregation of retinogeniculate projection was impaired by in vivo overexpression of SN25b, but not SN25b-T138A, in SACs. These results suggest that SN25 in developing SACs dampens the spatiotemporal properties of retinal waves and limits visual circuit refinement by phosphorylation at T138. Therefore, SN25 in SACs plays a profound role in regulating visual circuit refinement.

Published
2019

9. Metrology camera system of prime focus spectrograph for Subaru telescope

Author

Chi-Hung Yan, Jennifer Karr, Shu-Fu Hsu, Hung-Hsu Ling, James E. Gunn, Naruhisa Takato, Yuki Moritani, Atsushi Shimono, Naoyuki Tamura, Yen-Sang Hu, Hsin-Yo Chen, Yin-Chang Chang, Pin-Jie Huang, Cheuh-Yi Chou, Shiang-Yu Wang, Dan J. Reiley, Evans, Christopher J., Simard, Luc, and Takami, Hideki

Abstract

The Prime Focus Spectrograph (PFS) is a new optical/near-infrared multi-fiber spectrograph designed for the prime focus of the 8.2m Subaru telescope. PFS will cover a 1.3 degree diameter field with 2394 fibers to complement the imaging capabilities of Hyper SuprimeCam. To retain high throughput, the final positioning accuracy between the fibers and observing targets of PFS is required to be less than 10 μm. The metrology camera system (MCS) serves as the optical encoder of the fiber positioners for the configuring of fibers. MCS provides the fiber positions within a 5 microns error over the 45 cm focal plane. The information from MCS will be fed into the fiber positioner control system for the closed loop control. MCS locates at the Cassegrain focus of Subaru telescope to cover the whole focal plan with one 50M pixel Canon CMOS camera. It is a 380 mm aperture Schmidt type telescope which generates uniform spot size around 10 µm FWHM across the field for reasonable sampling of the point spreading function. An achromatic lens set is designed to remove the possible chromatic error due to the variation of the LED wavelength. Carbon fiber tubes are used to provide stable structure over the operation conditions without focus adjustments. The CMOS sensor can be read in 0.8 s to reduce the overhead for the fiber configuration. The positions of all fibers can be obtained within 0.5 s after the readout of the frame. This enables the overall fiber configuration to be less than 2 minutes. MCS is installed inside a standard Subaru Cassgrain Box. All components generate heat are located inside a glycol cooled cabinet to reduce the possible image motion due to the heat. The integration of MCS started from fall 2017 and it was delivered to Subaru in April 2018. In this report, the performance of MCS after the integration and verification process in ASIAA and the performance after the delivery to Subaru telescope are presented.

Published
2018

10. Hyper Suprime-Cam: System design and verification of image quality

Author

Masashi Chiba, Craig P. Loomis, Yoshihiko Yamada, Fumiaki Nakata, Yousuke Utsumi, Yutaka Komiyama, Toshifumi Futamase, Yao Cheng Lee, Yoshinori Miwa, Fumihiro Uraguchi, Paul T. P. Ho, Kyoji Nariai, Tomio Kurakami, Takashi Hamana, Yutaka Ezaki, Yoshiyuki Obuchi, Michael A. Strauss, Hideo Yokota, Dun Zen Jeng, Yukiko Kamata, Kazuyuki Kasumi, Satoru Iwamura, Eric J.-Y. Liaw, Naoki Yasuda, Hiroki Fujimori, Satoshi Kawanomoto, Hisanori Furusawa, Noboru Ito, Tadafumi Takata, Hisanori Suzuki, Atsushi J. Nishizawa, Chi Fang Chiu, Yusuke Hayashi, Robert Armstrong, Tomonori Usuda, Makoto Endo, Masamune Oguri, Hitomi Yamanoi, Hiroaki Aihara, Hitoshi Murayama, Robert H. Lupton, Kohei Imoto, Masaharu Muramatsu, Naoto Dojo, Michitaro Koike, Hiroyuki Ikeda, Kotaro Akutsu, Satoshi Miyazaki, Tomohisa Uchida, Satoshi Sofuku, James E. Gunn, Hiroshi Karoji, Masayuki Tanaka, Toru Matsuda, Masayuki Suzuki, Koei Yamamoto, Tomoaki Taniike, Daigo Tomono, Masahiro Takada, Edwin L. Turner, Kunio Takeshi, Yukie Oishi, Hironao Miyatake, Kazuhito Namikawa, H. Nakaya, Shoken Miyama, Tsang Chih Lai, Sogo Mineo, Norio Okada, Manobu M. Tanaka, Naoshi Sugiyama, Tsuyoshi Terai, James Bosch, Paul A. Price, Philip J. Tait, Shiang-Yu Wang, Yuki Okura, Yoshiyuki Doi, Hsin Yo Chen, Yoko Tanaka, Noboru Kawaguchi, Steve Bickerton, Tomoki Morokuma, Steward Smith, Cheng Lin Ho, and Yasuhito Miyazaki

Subjects
Physics, 010308 nuclear & particles physics, Space and Planetary Science, Image quality, business.industry, 0103 physical sciences, Systems design, Astronomy and Astrophysics, Instrumentation (computer programming), business, 010303 astronomy & astrophysics, 01 natural sciences, Computer hardware
Published
2017

11. The prototype cameras for trans-Neptunian automatic occultation survey

Author

Yin-Chang Chang, Hsin-Yo Chen, Stephen M. Amato, Jérôme Pratlong, Yen-Sang Hu, Andrew Szentgyorgyi, Shiang-Yu Wang, Matthew J. Lehner, Timothy Norton, John C. Geary, Hung-Hsu Ling, Pin-Jie Huang, and Paul Jorden

Subjects
CMOS sensor, business.industry, Computer science, Field of view, 01 natural sciences, Occultation, law.invention, 010309 optics, Telescope, Photometry (optics), Optics, Robotic telescope, law, 0103 physical sciences, business, 010303 astronomy & astrophysics, Computer hardware
Abstract

The Transneptunian Automated Occultation Survey (TAOS II) is a three robotic telescope project to detect the stellar occultation events generated by TransNeptunian Objects (TNOs). TAOS II project aims to monitor about 10000 stars simultaneously at 20Hz to enable statistically significant event rate. The TAOS II camera is designed to cover the 1.7 degrees diameter field of view of the 1.3m telescope with 10 mosaic 4.5k×2k CMOS sensors. The new CMOS sensor (CIS 113) has a back illumination thinned structure and high sensitivity to provide similar performance to that of the back-illumination thinned CCDs. Due to the requirements of high performance and high speed, the development of the new CMOS sensor is still in progress. Before the science arrays are delivered, a prototype camera is developed to help on the commissioning of the robotic telescope system. The prototype camera uses the small format e2v CIS 107 device but with the same dewar and also the similar control electronics as the TAOS II science camera. The sensors, mounted on a single Invar plate, are cooled to the operation temperature of about 200K as the science array by a cryogenic cooler. The Invar plate is connected to the dewar body through a supporting ring with three G10 bipods. The control electronics consists of analog part and a Xilinx FPGA based digital circuit. One FPGA is needed to control and process the signal from a CMOS sensor for 20Hz region of interests (ROI) readout.

Published
2016

12. High speed wide field CMOS camera for Transneptunian Automatic Occultation Survey

Author

Hsin-Yo Chen, Timothy Norton, Gabor Furesz, Yin-Chang Chang, Andrew Szentgyorgyi, Hung-Hsu Ling, John C. Geary, Pin-Jie Huang, Matthew J. Lehner, Shiang-Yu Wang, Stephen M. Amato, and Yen-Sang Hu

Subjects
Physics, CMOS sensor, Pixel, business.industry, Field of view, Occultation, law.invention, Telescope, Optics, Robotic telescope, CMOS, law, Field-programmable gate array, business, Remote sensing
Abstract

The Transneptunian Automated Occultation Survey (TAOS II) is a three robotic telescope project to detect the stellar occultation events generated by Trans Neptunian Objects (TNOs). TAOS II project aims to monitor about 10000 stars simultaneously at 20Hz to enable statistically significant event rate. The TAOS II camera is designed to cover the 1.7 degree diameter field of view (FoV) of the 1.3m telescope with 10 mosaic 4.5kx2k CMOS sensors. The new CMOS sensor has a back illumination thinned structure and high sensitivity to provide similar performance to that of the backillumination thinned CCDs. The sensor provides two parallel and eight serial decoders so the region of interests can be addressed and read out separately through different output channels efficiently. The pixel scale is about 0.6"/pix with the 16μm pixels. The sensors, mounted on a single Invar plate, are cooled to the operation temperature of about 200K by a cryogenic cooler. The Invar plate is connected to the dewar body through a supporting ring with three G10 bipods. The deformation of the cold plate is less than 10μm to ensure the sensor surface is always within ±40μm of focus range. The control electronics consists of analog part and a Xilinx FPGA based digital circuit. For each field star, 8×8 pixels box will be readout. The pixel rate for each channel is about 1Mpix/s and the total pixel rate for each camera is about 80Mpix/s. The FPGA module will calculate the total flux and also the centroid coordinates for every field star in each exposure.

Published
2014

13. Metrology Camera System of Prime Focus Spectrograph for Subaru Telescope

Author

Atsushi Shimono, Hung-Hsu Ling, Hiroshi Karoji, Chi-Hung Yan, Peter H. Mao, Hsin-Yo Chen, Youichi Ohyama, James E. Gunn, Richard C. Y. Chou, Shiang-Yu Wang, Naoyuki Tamura, Jennifer L. Karr, Yen-Sang Hu, Pin-Jie Huang, Naruhisa Takato, Hajime Sugai, Yin-Chang Chang, Ramsay, Suzanne K., McLean, Ian S., and Takami, Hideki

Subjects
Physics, CMOS sensor, business.industry, Aperture, Astrophysics::Instrumentation and Methods for Astrophysics, Cassegrain reflector, Physics::Optics, FOS: Physical sciences, Astrophysics::Cosmology and Extragalactic Astrophysics, Metrology, Optics, Cardinal point, Astrophysics::Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, business, Focus (optics), Subaru Telescope, Spectrograph, Instrumentation and Methods for Astrophysics (astro-ph.IM), Astrophysics::Galaxy Astrophysics
Abstract

The Prime Focus Spectrograph (PFS) is a new optical/near-infrared multi-fiber spectrograph designed for the prime focus of the 8.2m Subaru telescope. The metrology camera system of PFS serves as the optical encoder of the COBRA fiber motors for the configuring of fibers. The 380mm diameter aperture metrology camera will locate at the Cassegrain focus of Subaru telescope to cover the whole focal plane with one 50M pixel Canon CMOS sensor. The metrology camera is designed to provide the fiber position information within 5{\mu}m error over the 45cm focal plane. The positions of all fibers can be obtained within 1s after the exposure is finished. This enables the overall fiber configuration to be less than 2 minutes., Comment: 10 pages, 12 figures, SPIE Astronomical Telescopes and Instrumentation 2014

Published
2014
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14. Hyper Suprime-Cam

Author

Yukiko Kamata, Hisanori Suzuki, Yoko Tanaka, Paul A. Price, Makoto Endo, Satoshi Miyazaki, Yoshi Doi, Hiroshi Karoji, Yoshiyuki Obuchi, Masaharu Muramatsu, Naoki Yasuda, Yuki Fujimori, Yuki Okura, Takashi Hamana, Yutaka Ezaki, Masamune Oguri, Kazuhito Namikawa, Steve Bickerton, Daigo Tomono, Craig P. Loomis, Yousuke Utsumi, Hisanori Furusawa, N. Katayama, Hideo Yokota, Sogo Mineo, Tomio Kurakami, Hatsue Uekiyo, Tomoki Saito, Fumihiro Uraguchi, Yutaka Komiyama, Kyoji Nariai, Kunio Takeshi, Jun Nishizawa, Satoshi Kawanomoto, Hitomi Yamanoi, Yoshihiko Yamada, Tomohisa Uchida, Tadafumi Takata, Robert H. Lupton, Noboru Itoh, Yoshinori Miwa, Shiang-Yu Wang, Hiro Aihara, Tsuyoshi Terai, Manobu M. Tanaka, Hidehiko Nakaya, Michitaro Koike, James E. Gunn, Koei Yamamoto, Ryuichi Ebinuma, Toru Matsuda, Tomonori Usuda, Yuki Ishizuka, Hironao Miyatake, Yasuhito Miyazaki, Tomoki Morokuma, and Hsin-Yo Chen

Subjects
Optical axis, Physics, Primary mirror, Cardinal point, Optics, Pixel, business.industry, Field of view, Astrophysics, First light, business, Subaru Telescope, Weak gravitational lensing
Abstract

Hyper Suprime-Cam (HSC) is an 870 Mega pixel prime focus camera for the 8.2 m Subaru telescope. The wide field corrector delivers sharp image of 0.25 arc-sec FWHM in r-band over the entire 1.5 degree (in diameter) field of view. The collimation of the camera with respect to the optical axis of the primary mirror is realized by hexapod actuators whose mechanical accuracy is few microns. As a result, we expect to have seeing limited image most of the time. Expected median seeing is 0.67 arc-sec FWHM in i-band. The sensor is a p-ch fully depleted CCD of 200 micron thickness (2048 x 4096 15 μm square pixel) and we employ 116 of them to pave the 50 cm focal plane. Minimum interval between exposures is roughly 30 seconds including reading out arrays, transferring data to the control computer and saving them to the hard drive. HSC uniquely features the combination of large primary mirror, wide field of view, sharp image and high sensitivity especially in red. This enables accurate shape measurement of faint galaxies which is critical for planned weak lensing survey to probe the nature of dark energy. The system is being assembled now and will see the first light in August 2012.

Published
2012

15. Hyper Suprime-Cam: filter exchange unit and shutter

Author

Yao-Cheng Lee, Tsang-Chih Lai, Satoshi Kawanomoto, Fumihiro Uraguchi, Dun-Zen Jeng, Yousuke Utsumi, Satoru Iwamura, Yukiko Kamata, Shiang-Yu Wang, Yutaka Komiyama, Eric J.-Y. Liaw, Cheng-Lin Ho, Satoshi Miyazaki, Hidehiko Nakaya, Chi-Fang Chiu, Tomoki Morokuma, and Hsin-Yo Chen

Subjects
Physics, Mechanism (engineering), Cardinal point, Optical path, Optics, Filter (video), Aperture, business.industry, Shutter, Envelope (mathematics), business, Subaru Telescope
Abstract

We have developed a filter exchange unit (FEU) and a shutter of Hyper Suprime-Cam (HSC). FEU consists of two parts; the alignment mechanism of the filter in the optical path and a jukebox of the filters. The alignment mechanism can guarantee 10 μm position stability with respect to the focal plane CCDs. On the exchange sequence, a motorized cart grabs and pushes the filter from the jukebox. Each jukebox has 3 slots and we have two identical jukeboxes. The operation is fully automated and the entire exchange sequence takes 16 minutes. Also, we developed the focal-plane shutter with 1,030 mm diameter envelope and 60 mm thickness while having 600 mm aperture. We report the detail of design and implementation of the shutter and FEU, and installation procedure of FEU.

Published
2012

16. Prime focus spectrograph: Subaru's future

Author

Hajime Sugai, Hiroshi Karoji, Naruhisa Takato, Naoyuki Tamura, Atsushi Shimono, Youichi Ohyama, Akitoshi Ueda, Hung-Hsu Ling, Marcio Vital de Arruda, Robert H. Barkhouser, Charles L. Bennett, Steve Bickerton, David F. Braun, Robin J. Bruno, Michael A. Carr, João Batista de Carvalho Oliveira, Yin-Chang Chang, Hsin-Yo Chen, Richard G. Dekany, Tania Pereira Dominici, Richard S. Ellis, Charles D. Fisher, James E. Gunn, Timothy Heckman, Paul T. P. Ho, Yen-Shan Hu, Marc Jaquet, Jennifer Karr, Masahiko Kimura, Olivier C. Le Fèvre, David Le Mignant, Craig Loomis, Robert H. Lupton, Fabrice Madec, Lucas Marrara, Laurent Martin, Hitoshi Murayama, Antonio Cesar de Oliveira, Claudia Mendes de Oliveira, Ligia Souza de Oliveira, Joseph D. Orndorff, Rodrigo M. P. de Paiva Vilaça, Vanessa B. d. P. Macanhan, Eric Prieto, Jesulino Bispo dos Santos, Michael Seiffert, Stephen A. Smee, Roger M. Smith, Laerte Sodré, David N. Spergel, Christian Surace, Sebastien Vives, Shiang-Yu Wang, Chi-Hung Yan, McLean, Ian S., Ramsay, Suzanne K., Takami, Hideki, Laboratoire d'Astrophysique de Marseille (LAM), and Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)

Subjects
Physics, business.industry, FOS: Physical sciences, Cassegrain reflector, 01 natural sciences, 7. Clean energy, Metrology, 010309 optics, Optics, Cardinal point, 0103 physical sciences, [INFO]Computer Science [cs], Astrophysics - Instrumentation and Methods for Astrophysics, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph], business, Focus (optics), Subaru Telescope, Instrumentation and Methods for Astrophysics (astro-ph.IM), 010303 astronomy & astrophysics, Spectrograph, ComputingMilieux_MISCELLANEOUS
Abstract

The Prime Focus Spectrograph (PFS) of the Subaru Measurement of Images and Redshifts (SuMIRe) project has been endorsed by Japanese community as one of the main future instruments of the Subaru 8.2-meter telescope at Mauna Kea, Hawaii. This optical/near-infrared multi-fiber spectrograph targets cosmology with galaxy surveys, Galactic archaeology, and studies of galaxy/AGN evolution. Taking advantage of Subaru's wide field of view, which is further extended with the recently completed Wide Field Corrector, PFS will enable us to carry out multi-fiber spectroscopy of 2400 targets within 1.3 degree diameter. A microlens is attached at each fiber entrance for F-ratio transformation into a larger one so that difficulties of spectrograph design are eased. Fibers are accurately placed onto target positions by positioners, each of which consists of two stages of piezo-electric rotary motors, through iterations by using back-illuminated fiber position measurements with a wide-field metrology camera. Fibers then carry light to a set of four identical fast-Schmidt spectrographs with three color arms each: the wavelength ranges from 0.38 {\mu}m to 1.3 {\mu}m will be simultaneously observed with an average resolving power of 3000. Before and during the era of extremely large telescopes, PFS will provide the unique capability of obtaining spectra of 2400 cosmological/astrophysical targets simultaneously with an 8-10 meter class telescope. The PFS collaboration, led by IPMU, consists of USP/LNA in Brazil, Caltech/JPL, Princeton, & JHU in USA, LAM in France, ASIAA in Taiwan, and NAOJ/Subaru., Comment: 13 pages, 11 figures, submitted to "Ground-based and Airborne Instrumentation for Astronomy IV, Ian S. McLean, Suzanne K. Ramsay, Hideki Takami, Editors, Proc. SPIE 8446 (2012)"

Published
2012

17. Hyper Suprime-Cam: camera design

Author

Yoshinori Miwa, Fumihiro Uraguchi, Dun-Zen Jeng, Tomoki Morokuma, Yukiko Kamata, Chyi-Fong Chiu, Hidehiko Nakaya, Hisanori Furusawa, Hiroaki Aihara, Hideo Yokota, Hironao Miyatake, Yutaka Komiyama, Toru Matsuda, Tomohisa Uchida, Yosuke Utsumi, Eric J.-Y. Liaw, Yoshiyuki Obuchi, Yoko Tanaka, Hsin-Yo Chen, Hiroshi Karoji, Kyoji Nariai, Shiang-Yu Wang, Hiroki Fujimori, Yuki Okura, Sogo Mineo, Makoto Endo, Satoshi Miyazaki, Yutaka Ezaki, and Satoshi Kawanomoto

Subjects
Physics, Image quality, business.industry, Field of view, First light, law.invention, Optical axis, Telescope, Cardinal point, Optics, law, Subaru Telescope, business, Focus (optics)
Abstract

Hyper Suprime-Cam (HSC) is the next generation wide-field imager for the prime focus of Subaru Telescope, which is scheduled to receive its first light in 2011. Combined with a newly built wide-field corrector, HSC covers 1.5 degree diameter field of view with 116 fully-depleted CCDs. In this presentation, we summarize the details of the camera design: the wide-field corrector, the prime focus unit, the CCD dewar and the peripheral devices. The wide-field corrector consists of 5 lenses with lateral shift type doublet ADC element. The novel design guarantees the excellent image quality (D80

Published
2010

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