Abstract: An optical communication device according to an embodiment of the present invention includes: a heat sink integrally having a plurality of contact portions respectively corresponding to the plurality of the optical transceivers, and a heat transfer portion bound to a casing so as to be able to transfer heat to the casing; a plurality of cage members configured to respectively accommodate the plurality of the optical transceivers, and having openings so as to allow the optical transceivers to be partially exposed to the contact portion side, respectively; a holding unit configured to hold the plurality of the cage members inside the casing in a state where the openings correspond to the contact portions, respectively; and an elastic member configured to bring the plurality of the optical transceivers into thermal contact with the plurality of the contact portions, respectively, by pressing each of the plurality of the cage members toward the heat sink side.

Abstract: An optical network unit according to one manner of the present invention includes an optical transceiver configured to be connected to an optical communication line, a plurality of media access control (MAC) processing units, a plurality of user network interface (UNI) ports each connected to one MAC processing unit of the plurality of MAC processing units, and an integration unit integrating a plurality of communication paths connected to the plurality of MAC processing units, respectively, and connected to the optical transceiver.

Abstract: An optical communication apparatus according to an embodiment of the present invention includes: a light emitting element; a transmission driver that drives the light emitting element; a light receiving element capable of changing a multiplication factor by a bias voltage; a temperature sensor; a computing unit that calculates a drive rate of the transmission driver; and an adjusting unit that adjusts the bias voltage applied to the light receiving element. The adjusting unit adjusts the bias voltage by linear computation using a plurality of target values of the bias voltage for combinations of a plurality of temperatures and a plurality of drive rates, based on a temperature detected by the temperature sensor and a result of calculation of the drive rate.

Abstract: An optical communication device according to an embodiment of the present invention includes: a heat sink integrally having a plurality of contact portions respectively corresponding to the plurality of the optical transceivers, and a heat transfer portion bound to a casing so as to be able to transfer heat to the casing; a plurality of cage members configured to respectively accommodate the plurality of the optical transceivers, and having openings so as to allow the optical transceivers to be partially exposed to the contact portion side, respectively; a holding unit configured to hold the plurality of the cage members inside the casing in a state where the openings correspond to the contact portions, respectively; and an elastic member configured to bring the plurality of the optical transceivers into thermal contact with the plurality of the contact portions, respectively, by pressing each of the plurality of the cage members toward the heat sink side.

Abstract: There are provided an optical transceiver, an optical network unit, and an optical transceiver control method that control the operating state of the optical transceiver and reduce the number of terminals of the optical transceiver. An optical transceiver includes: a transmitting and receiving unit that transmits and receives optical signals and that has three or more states for transmission or reception of the optical signals, the states transitioning in sequence; a terminal for receiving a voltage or current as operation instruction information indicating in which one of the states operation is to be performed; and a determining unit for determining one of the states indicated by the operation instruction information, based on a magnitude of the voltage or current received by the terminal. The transmitting and receiving unit operates in the one of the states determined by the determining unit.

Abstract: An optical signal repeater includes a plurality of ports, each configured to be connectable to both of a first optical transceiver for transmitting and receiving an optical signal to and from the optical line terminal and a second optical transceiver for transmitting and receiving an optical signal to and from the optical network unit. The optical signal repeater further includes a port switching control unit which switches each of the plurality of ports between a first port adapted to the first optical transceiver and a second port adapted to the second optical transceiver and a path switching unit configured to switch a transmission path between the plurality of ports. The path switching unit includes an aggregation unit configured to aggregate the transmission paths from the second ports. The optical signal repeater further includes a path switching control unit configured to control the path switching unit.

Abstract: A drive circuit includes a bias current supply circuit for supplying a bias current to a light-emitting element and a modulated current supply circuit for supplying a modulated current to the light-emitting element, and has a first path through which the bias current flows, a second path including a path for supplying the modulated current to the light-emitting element from the modulated current supply circuit, through which a current returns to the bias current supply circuit through the modulated current supply circuit from the bias current supply circuit without going through the light-emitting element when the bias current flows, and a third path which is joined to the second path in the modulated current supply circuit and has an adjusting resistance before a junction, through which a current flows through the adjusting resistance to the bias current supply circuit when the bias current flows.

Abstract: An optical communication apparatus according to an embodiment of the present invention includes: a light emitting element; a transmission driver that drives the light emitting element; a light receiving element capable of changing a multiplication factor by a bias voltage; a temperature sensor; a computing unit that calculates a drive rate of the transmission driver; and an adjusting unit that adjusts the bias voltage applied to the light receiving element. The adjusting unit adjusts the bias voltage by linear computation using a plurality of target values of the bias voltage for combinations of a plurality of temperatures and a plurality of drive rates, based on a temperature detected by the temperature sensor and a result of calculation of the drive rate.

Abstract: An optical network unit according to one manner of the present invention includes an optical transceiver configured to be connected to an optical communication line, a plurality of media access control (MAC) processing units, a plurality of user network interface (UNI) ports each connected to one MAC processing unit of the plurality of MAC processing units, and an integration unit integrating a plurality of communication paths connected to the plurality of MAC processing units, respectively, and connected to the optical transceiver.

Abstract: An optical communication module includes a modulation current supply circuit for supplying to a light-emitting element for transmitting a burst optical signal, a modulation current having magnitude in accordance with a logical value of data to be transmitted, a light-receiving element for monitoring, for outputting a current in accordance with intensity of light received from the light-emitting element, a measurement unit for measuring an output current from the light-receiving element for monitoring at set measurement timing, an adjustment unit for adjusting magnitude of the modulation current based on a result of measurement of the output current by the measurement unit, and a measurement timing setting unit for setting measurement timing based on a control signal for controlling transmission of the burst optical signal.

Abstract: A drive circuit includes a bias current supply circuit for supplying a bias current to a light-emitting element and a modulated current supply circuit for supplying a modulated current to the light-emitting element, and has a first path through which the bias current flows, a second path including a path for supplying the modulated current to the light-emitting element from the modulated current supply circuit, through which a current returns to the bias current supply circuit through the modulated current supply circuit from the bias current supply circuit without going through the light-emitting element when the bias current flows, and a third path which is joined to the second path in the modulated current supply circuit and has an adjusting resistance before a junction, through which a current flows through the adjusting resistance to the bias current supply circuit when the bias current flows.

Abstract: A drive circuit includes a bias current supply circuit for supplying a bias current to a light-emitting device for transmitting an optical signal, the light-emitting device included in a light-emitting circuit; and a modulation current supply circuit for supplying a modulation current of a magnitude according to a logical value of data to be transmitted, to the light-emitting device. The modulation current supply circuit includes a differential drive circuit for switching whether to supply a current to the light-emitting device, according to the logical value of the data; and a termination resistor connected between differential outputs of the differential drive circuit. The differential drive circuit and the light-emitting circuit are DC-coupled to each other, and power supply of the current supplied to the light-emitting device by the differential drive circuit is supplied from the light-emitting circuit.

Abstract: An optical communication module includes a modulation current supply circuit for supplying to a light-emitting element for transmitting a burst optical signal, a modulation current having magnitude in accordance with a logical value of data to be transmitted, a light-receiving element for monitoring, for outputting a current in accordance with intensity of light received from the light-emitting element, a measurement unit for measuring an output current from the light-receiving element for monitoring at set measurement timing, an adjustment unit for adjusting magnitude of the modulation current based on a result of measurement of the output current by the measurement unit, and a measurement timing setting unit for setting measurement timing based on a control signal for controlling transmission of the burst optical signal.

Abstract: A drive circuit includes a bias current supply circuit for supplying a bias current to a light-emitting device for transmitting an optical signal, the light-emitting device included in a light-emitting circuit; and a modulation current supply circuit for supplying a modulation current of a magnitude according to a logical value of data to be transmitted, to the light-emitting device. The modulation current supply circuit includes a differential drive circuit for switching whether to supply a current to the light-emitting device, according to the logical value of the data; and a termination resistor connected between differential outputs of the differential drive circuit. The differential drive circuit and the light-emitting circuit are DC-coupled to each other, and power supply of the current supplied to the light-emitting device by the differential drive circuit is supplied from the light-emitting circuit.

Abstract: There are provided an optical transceiver, an optical network unit, and an optical transceiver control method that control the operating state of the optical transceiver and reduce the number of terminals of the optical transceiver. An optical transceiver includes: a transmitting and receiving unit that transmits and receives optical signals and that has three or more states for transmission or reception of the optical signals, the states transitioning in sequence; a terminal for receiving a voltage or current as operation instruction information indicating in which one of the states operation is to be performed; and a determining unit for determining one of the states indicated by the operation instruction information, based on a magnitude of the voltage or current received by the terminal. The transmitting and receiving unit operates in the one of the states determined by the determining unit.