We have been working on a project called ParaBIT (for parallel inter-board optical interconnection technology) to achieve large-capacity switching systems. The ParaBIT module being developed as the first step in this project is a front-end module with 40 channels providing throughput of 28 Gb/s, cost-effectiveness and compactness. To realize the module, this project has developed five novel technologies: (1) 850-nm 10-ch Vertical-cavity Surface-emitting laser (VCSEL) arrays as very cost-effective light sources, (2) new high-density multiport bare fiber connectors that do not need a ferrule and spring, (3) passive optical alignment using polymeric optical waveguide film with a 45-degree mirror for coupling to the optical array chips and the waveguide, (4) transferred multichip bonding to mount optical array chips on a substrate with a positioning error of only a few micrometers, and (5) simple electronic circuits with a fixed-decision-level receiver and an APC-less transmitter, and low power consumption. Experimental results show that the design targets of throughput of 700 Mb/s per channel and a compact and cost-effectiveness structure were met. Thus, ParaBIT is a promising technology for large-capacity switching systems.
Kosuke KATSURA
Yasuhiro ANDO
Mitsuo USUI
Akira OHKI
Nobuo SATO
Nobuaki MATSUURA
Nobuyuki TANAKA
Toshiaki KAGAWA
Makoto HIKITA
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Kosuke KATSURA, Yasuhiro ANDO, Mitsuo USUI, Akira OHKI, Nobuo SATO, Nobuaki MATSUURA, Nobuyuki TANAKA, Toshiaki KAGAWA, Makoto HIKITA, "ParaBIT: Parallel Optical Interconnection for Large-Capacity ATM Switching Systems" in IEICE TRANSACTIONS on Electronics,
vol. E82-C, no. 2, pp. 360-369, February 1999, doi: .
Abstract: We have been working on a project called ParaBIT (for parallel inter-board optical interconnection technology) to achieve large-capacity switching systems. The ParaBIT module being developed as the first step in this project is a front-end module with 40 channels providing throughput of 28 Gb/s, cost-effectiveness and compactness. To realize the module, this project has developed five novel technologies: (1) 850-nm 10-ch Vertical-cavity Surface-emitting laser (VCSEL) arrays as very cost-effective light sources, (2) new high-density multiport bare fiber connectors that do not need a ferrule and spring, (3) passive optical alignment using polymeric optical waveguide film with a 45-degree mirror for coupling to the optical array chips and the waveguide, (4) transferred multichip bonding to mount optical array chips on a substrate with a positioning error of only a few micrometers, and (5) simple electronic circuits with a fixed-decision-level receiver and an APC-less transmitter, and low power consumption. Experimental results show that the design targets of throughput of 700 Mb/s per channel and a compact and cost-effectiveness structure were met. Thus, ParaBIT is a promising technology for large-capacity switching systems.
URL: https://global.ieice.org/en_transactions/electronics/10.1587/e82-c_2_360/_p
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@ARTICLE{e82-c_2_360,
author={Kosuke KATSURA, Yasuhiro ANDO, Mitsuo USUI, Akira OHKI, Nobuo SATO, Nobuaki MATSUURA, Nobuyuki TANAKA, Toshiaki KAGAWA, Makoto HIKITA, },
journal={IEICE TRANSACTIONS on Electronics},
title={ParaBIT: Parallel Optical Interconnection for Large-Capacity ATM Switching Systems},
year={1999},
volume={E82-C},
number={2},
pages={360-369},
abstract={We have been working on a project called ParaBIT (for parallel inter-board optical interconnection technology) to achieve large-capacity switching systems. The ParaBIT module being developed as the first step in this project is a front-end module with 40 channels providing throughput of 28 Gb/s, cost-effectiveness and compactness. To realize the module, this project has developed five novel technologies: (1) 850-nm 10-ch Vertical-cavity Surface-emitting laser (VCSEL) arrays as very cost-effective light sources, (2) new high-density multiport bare fiber connectors that do not need a ferrule and spring, (3) passive optical alignment using polymeric optical waveguide film with a 45-degree mirror for coupling to the optical array chips and the waveguide, (4) transferred multichip bonding to mount optical array chips on a substrate with a positioning error of only a few micrometers, and (5) simple electronic circuits with a fixed-decision-level receiver and an APC-less transmitter, and low power consumption. Experimental results show that the design targets of throughput of 700 Mb/s per channel and a compact and cost-effectiveness structure were met. Thus, ParaBIT is a promising technology for large-capacity switching systems.},
keywords={},
doi={},
ISSN={},
month={February},}
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TY - JOUR
TI - ParaBIT: Parallel Optical Interconnection for Large-Capacity ATM Switching Systems
T2 - IEICE TRANSACTIONS on Electronics
SP - 360
EP - 369
AU - Kosuke KATSURA
AU - Yasuhiro ANDO
AU - Mitsuo USUI
AU - Akira OHKI
AU - Nobuo SATO
AU - Nobuaki MATSUURA
AU - Nobuyuki TANAKA
AU - Toshiaki KAGAWA
AU - Makoto HIKITA
PY - 1999
DO -
JO - IEICE TRANSACTIONS on Electronics
SN -
VL - E82-C
IS - 2
JA - IEICE TRANSACTIONS on Electronics
Y1 - February 1999
AB - We have been working on a project called ParaBIT (for parallel inter-board optical interconnection technology) to achieve large-capacity switching systems. The ParaBIT module being developed as the first step in this project is a front-end module with 40 channels providing throughput of 28 Gb/s, cost-effectiveness and compactness. To realize the module, this project has developed five novel technologies: (1) 850-nm 10-ch Vertical-cavity Surface-emitting laser (VCSEL) arrays as very cost-effective light sources, (2) new high-density multiport bare fiber connectors that do not need a ferrule and spring, (3) passive optical alignment using polymeric optical waveguide film with a 45-degree mirror for coupling to the optical array chips and the waveguide, (4) transferred multichip bonding to mount optical array chips on a substrate with a positioning error of only a few micrometers, and (5) simple electronic circuits with a fixed-decision-level receiver and an APC-less transmitter, and low power consumption. Experimental results show that the design targets of throughput of 700 Mb/s per channel and a compact and cost-effectiveness structure were met. Thus, ParaBIT is a promising technology for large-capacity switching systems.
ER -