Competition of two-photon and one-photon absorption in Si-APD was studied. Device should be cooled down in order to clearly observe two-photon absorption at low illumination intensity. Passive Geiger mode operation was studied to sensitively detect small number of carriers generated by two-photon absorption. The illumination intensity dependence of the photocurrent pulse count number is well explained by taking into account the two absorption mechanisms and a dead time period that depends on bias voltage.

Detection efficiency and dark count of a Geiger mode single photon detection avalanche photodiode was studied by a numerical simulation. The ionization process triggered by a single hole injection was simulated at a bias voltage slightly greater than the avalanche breakdown voltage for calculation of the detection efficiency. Tunneling effect in the multiplication layer was taken into account for the dark count simulation. In the gated-mode operation, the avalanche build-up time also affects on the signal to noise ratio. The multiplication layer thickness is a key parameter for the device performances.

We have proposed parallel optical interconnection technology, or ParaBIT, for high-throughput, low-cost optical interconnections and already developed a prototype parallel optical interconnect module called "ParaBIT-0," which has a total throughput of 28 Gb/s (700 Mb/s 40 channels). We are now developing a compact, high-throughput module called "ParaBIT-1," which has a total throughput of 60 Gb/s (1.25 Gb/s 48 channels) and is designed to achieve the highest-ever throughput density of 3.3 Gb/s/cc. In this paper, we describe the packaging structure, optical coupling structure and transmission characteristics of ParaBIT-1. We also discuss the technical prospect of realizing a parallel optical interconnect module with the bit rate of 2.5 Gb/s/ch.

VCSEL output light polarization was controlled by fabricating devices on (311) substrate. Stability was improved by introducing compressive strain to the quantum wells in the active layer. In experiments, the power penalty due to polarization-dependent loss in the transmission line was negligible for both VCSELs with unstrained and strained quantum well active layers on (311)B substrate. The sensitivity at 2.5 Gbps was improved in a device with a strained active layer because the intensity noise due to the polarization instability was reduced. These characteristics are discussed and compared to calculated results.

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.

The performance of avalanche photodiodes with deep guard rings for Geiger mode operation is studied. The electric field distribution is calculated using the finite element method and the carrier multiplication characteristic is calculated along typical lines in the device. The nonlinear dependence of the ionization rates on the electric field strength can make a guard ring less effective in Geiger mode operation. The maximum single photon detection efficiency that can be obtained without breakdown at the guard ring is calculated for several structure parameters. It is shown that the single photon detection efficiency strongly depends on the guard ring design.

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.

A novel base station for microwave radio-on-fiber systems is proposed. It consists of an L-band electroabsorption modulator and a uni-traveling-carrier photodiode. We show it is applicable for bias-free operation and full-duplex transmission and demonstrate 100-Mbit/s bidirectional data transmission in the 5-GHz band.