Proceedings Article | 28 July 2014
Antonio Cesar de Oliveira, Lígia Souza de Oliveira, Marcio de Arruda, Lucas Souza Marrara, Leandro dos Santos, Décio Ferreira, Jesulino dos Santos, Josimar Rosa, Orlando Junior, Jeferson Pereira, Bruno Castilho, Clemens Gneiding, Laerte Junior, Claudia de Oliveira, James Gunn, Akitoshi Ueda, Naruhisa Takato, Atsushi Shimono, Hajime Sugai, Hiroshi Karoji, Masahiko Kimura, Naoyuki Tamura, Shiang-Yu Wang, Graham Murray, David Le Mignant, Fabrice Madec, Marc Jaquet, Sebastien Vives, Charlie Fisher, David Braun, Mark Schwochert, Daniel Reiley
KEYWORDS: Connectors, Optical fibers, Spectrographs, Telescopes, Microlens, Interfaces, Optical fiber cables, Fiber optics, Structured optical fibers, Optical fabrication
FOCCoS, "Fiber Optical Cable and Connector System" has the main function of capturing the direct light from the focal plane of Subaru Telescope using optical fibers, each one with a microlens in its tip, and conducting this light through a route containing connectors to a set of four spectrographs. The optical fiber cable is divided in 3 different segments called Cable A, Cable B and Cable C. Multi-fibers connectors assure precise connection among all optical fibers of the segments, providing flexibility for instrument changes. To assure strong and accurate connection, these sets are arranged inside two types of assemblies: the Tower Connector, for connection between Cable C and Cable B; and the Gang Connector, for connection between Cable B and Cable A. Throughput tests were made to evaluate the efficiency of the connections. A lifetime test connection is in progress. Cable C is installed inside the PFI, Prime Focus Instrument, where each fiber tip with a microlens is bonded to the end of the shaft of a 2-stage piezo-electric rotatory motor positioner; this assembly allows each fiber to be placed anywhere within its patrol region, which is 9.5mm diameter.. Each positioner uses a fiber arm to support the ferrule, the microlens, and the optical fiber. 2400 of these assemblies are arranged on a motor bench plate in a hexagonal-closed-packed disposition. All optical fibers from Cable C, protected by tubes, pass through the motors’ bench plate, three modular plates and a strain relief box, terminating at the Tower Connector. Cable B is permanently installed at Subaru Telescope structure, as a link between Cable C and Cable A. This cable B starts at the Tower Connector device, placed on a lateral structure of the telescope, and terminates at the Gang Connector device. Cable B will be routed to minimize the compression, torsion and bending caused by the cable weight and telescope motion. In the spectrograph room, Cable A starts at the Gang Connector, crosses a distribution box and terminates in a slit device. Each slit device receives approximately 600 optical fibers, linearly arrayed in a curve for better orientation of the light to the spectrograph collimator mirror. Four sets of Gang Connectors, distribution boxes and Slit devices complete one Cable A. This paper will review the general design of the FOCCoS subsystem, methods used to manufacture the involved devices, and the needed tests results to evaluate the total efficiency of the set.
