Abstract: An optical communication system includes: transmitting apparatuses that convert a first data signal into a plurality of optical-signal packet signals; optical couplers that combine optical-signal packet signals and split the combined optical-signal packet signals into a plurality of optical-signal transmission signals; receiving apparatuses that receive the optical-signal transmission signals and convert the optical-signal transmission signals into a second data signal and a controller that controls operation of the transmitting apparatuses and the receiving apparatuses. The transmitting apparatuses transmit the plurality of optical-signal packet signals, allocating communication resources thereto to prevent the transmitted optical-signal packet signals from colliding with the optical-signal packet signals transmitted from the other transmitting apparatuses.

Abstract: A single-fiber bidirectional optical ring system includes: a central station; slave stations; and a network which connects the central station and the slave stations in a ring shape by optical fibers.

Abstract: An optical communication system includes: a plurality of optical transmission devices converting a first data signal that is an electrical signal into an optical packet signal; an optical coupler coupling optical packet signals; an optical coupler branching the optical transmission signal generated through coupling; a plurality of optical reception devices converting the optical transmission signal generated through branching into a second data signal that is an electrical signal; and a control unit controlling operation of the optical transmission devices and the optical reception devices.

Abstract: An optical communication system includes a plurality of optical transmitters, a plurality of first optical couplers provided respectively corresponding to the plurality of optical transmitters, a plurality of optical receivers, and a plurality of second optical couplers provided respectively corresponding to the plurality of optical receivers, in which each of the plurality of first optical couplers splits an optical signal transmitted by the corresponding optical transmitter and outputs the optical signal to each of the plurality of second optical couplers, each of the plurality of second optical couplers merges a plurality of optical signals output from the plurality of first optical couplers and outputs the merged signal to the corresponding optical receiver, and the plurality of optical transmitters alternately transmits the optical signals.

Abstract: An optical receiver includes a transimpedance amplifier that converts a current signal output from a light-receiving element that receives an optical signal into a voltage signal, and has a variable conversion gain when performing the conversion, a gain control circuit that detects the bottom voltage of the voltage signal output from the transimpedance amplifier and controls the conversion gain of the transimpedance amplifier based on a result of the detection, and a signal detection circuit that outputs a signal detection signal indicating a signal detection result of whether or not an optical signal is being received. When the signal detection signal indicates a transition from an optical signal non-reception state to an optical signal reception state, the gain control circuit terminates the control of the conversion gain and holds the value of the conversion gain at a point in time when the control of the conversion gain is terminated.

Abstract: A signal detection circuit includes: a first DC voltage remover that removes a DC voltage from an input differential signal; a limiting amplifier that adjusts an amplitude of the input differential signal; a reset signal generator that generates an internal reset signal on the basis of the input differential signal obtained after the amplitude is adjusted; a first bias voltage applying unit that generates a differential signal for detection by applying a bias voltage to the signal from which the DC voltage is removed; and a flip-flop circuit that generates a packet detection signal by holding a state indicating input of a packet signal on the basis of the differential signal for detection and releasing the holding on the basis of the internal reset signal. The reset signal generator includes: a differential single-phase conversion circuit; a voltage holding circuit; and a voltage comparison circuit.

Abstract: A signal detection circuit includes: a first DC voltage remover that removes a DC voltage from an input differential signal; a limiting amplifier that adjusts an amplitude of the input differential signal; a reset signal generator that generates an internal reset signal on the basis of the input differential signal obtained after the amplitude is adjusted; a first bias voltage applying unit that generates a differential signal for detection by applying a bias voltage to the signal from which the DC voltage is removed; and a flip-flop circuit that generates a packet detection signal by holding a state indicating input of a packet signal on the basis of the differential signal for detection and releasing the holding on the basis of the internal reset signal. The reset signal generator includes: a differential single-phase conversion circuit; a voltage holding circuit; and a voltage comparison circuit.

Abstract: A burst light receiver includes a booster circuit that generates a voltage applied to an avalanche photodiode, a first path in which a resistor to step down the voltage generated by the booster circuit is inserted, a second path provided in parallel to the first path, a switch circuit that is provided between the booster circuit and the first and second paths to select the first path or the second path, a current detecting circuit that controls the switch circuit in such a manner that the booster circuit is connected to the first path when a value of a current flowing from the booster circuit to the avalanche photodiode becomes equal to or larger than a first threshold, and the booster circuit is connected to the second path when the value of the current becomes smaller than a second threshold.

Abstract: Provided is an emphasis circuit capable of obtaining a desired emphasis amount with which waveform deterioration of an output signal in a high frequency band (high frequency band deterioration) is suppressed without increasing power consumption (current consumption). In the emphasis circuit, a baseband amplifier section and a peaking amplifier section are connected in parallel to each other, and respective drive current setting sections are adjusted to adjust respective drive current values thereof so that the sum of the drive current value of the baseband amplifier section and the drive current value of the peaking amplifier section may be constant.

Abstract: A burst-signal reception circuit that receives a differential signal of a burst signal input via a preamplifier. The burst-signal reception circuit includes a differential amplifier to which the differential signal is input via capacitors, an average detection circuit that detects an average of a differential input signal to the differential amplifier, and a differential-offset cancel circuit that operates to cancel a DC voltage level difference of the differential input signal on the basis of output signals of the average detection circuit. Average detection speed of the average detection circuit is configured to be switched according to presence or absence of burst signal reception. The average detection speed is switched to a high-speed side in a head portion of the burst signal and switched to a low-speed side in portions other than the head portion.

Abstract: A burst-signal reception circuit that receives a differential signal of a burst signal input via a preamplifier. The burst-signal reception circuit includes a differential amplifier to which the differential signal is input via capacitors, an average detection circuit that detects an average of a differential input signal to the differential amplifier, and a differential-offset cancel circuit that operates to cancel a DC voltage level difference of the differential input signal on the basis of output signals of the average detection circuit. Average detection speed of the average detection circuit is configured to be switched according to presence or absence of burst signal reception. The average detection speed is switched to a high-speed side in a head portion of the burst signal and switched to a low-speed side in portions other than the head portion.

Abstract: A burst-mode receiver for receiving burst optical signals having different intensities by a reversely connected APD, including: a current detection circuit outputting a photocurrent that is generated by APD and is output from a current mirror circuit (CMC) as a voltage proportional to the photocurrent, the CMC being connected in series between a power supply and APD; a peak detector circuit detecting and holding a peak value of the output voltage of the current detection circuit; a resistor connection switching circuit, which is inserted between the CMC and APD, for connecting a series resistor to APD in series by switching; and a comparator outputting a switching signal for switching the resistor connection switching circuit so that the series resistor is connected to APD in series in a case where a voltage detected by the peak detector circuit is equal to or more than a predetermined threshold.

Abstract: An optical receiver includes a light receiving element configured to convert an input light signal into an electric current, a current mirror circuit including a reference current side transistor and a mirror current side transistor, the transistor being connected to the light receiving element, a current-voltage conversion circuit configured to convert an output current from the transistor into a voltage and output the voltage as a light reception level monitor voltage of the light receiving element, and a current sink circuit connected to the transistor and configured to feed an electric current to the transistor.

Abstract: A burst-mode receiver for receiving burst optical signals having different intensities by a reversely connected APD, including: a current detection circuit outputting a photocurrent that is generated by APD and is output from a current mirror circuit (CMC) as a voltage proportional to the photocurrent, the CMC being connected in series between a power supply and APD; a peak detector circuit detecting and holding a peak value of the output voltage of the current detection circuit; a resistor connection switching circuit, which is inserted between the CMC and APD, for connecting a series resistor to APD in series by switching; and a comparator outputting a switching signal for switching the resistor connection switching circuit so that the series resistor is connected to APD in series in a case where a voltage detected by the peak detector circuit is equal to or more than a predetermined threshold.

Abstract: Provided is an emphasis circuit capable of obtaining a desired emphasis amount with which waveform deterioration of an output signal in a high frequency band (high frequency band deterioration) is suppressed without increasing power consumption (current consumption). In the emphasis circuit, a baseband amplifier section and a peaking amplifier section are connected in parallel to each other, and respective drive current setting sections are adjusted to adjust respective drive current values thereof so that the sum of the drive current value of the baseband amplifier section and the drive current value of the peaking amplifier section may be constant.

Abstract: An optical receiver includes a light receiving element configured to convert an input light signal into an electric current, a current mirror circuit including a reference current side transistor and a mirror current side transistor, the transistor being connected to the light receiving element, a current-voltage conversion circuit configured to convert an output current from the transistor into a voltage and output the voltage as a light reception level monitor voltage of the light receiving element, and a current sink circuit connected to the transistor and configured to feed an electric current to the transistor.

Abstract: To enable optical line terminal to detect input disconnection of optical burst signal accurately in spite of changes of transmission rate of optical-burst signal received from optical network unit, OLT (optical line terminal) includes photo-detector for converting the optical-burst signal received to current signal; preamplifier for converting the current signal to voltage signal; input disconnection detecting circuit for comparing output amplitude of preamplifier with threshold, and for outputting input disconnection signal indicating disconnection of input of the optical-burst signal; and control circuit for controlling conversion gain of preamplifier in a manner that the conversion gain becomes conversion gain corresponding to the transmission rate of the optical-burst signal received, and for controlling input disconnection detecting circuit in a manner that it outputs the input disconnection signal in response to the threshold corresponding to the transmission rate of the optical-burst signal received.

Abstract: A laser diode drive circuit includes a laser diode (LD), a modulation-current differential drive circuit, a bias-current differential drive circuit, a first inductance connected between an anode of the LD and a positive power source, a second inductance connected between a cathode of the LD and a negative-phase output terminal of the bias-current differential drive circuit, a first resistor connected to a connection point of the anode of the LD and the first inductance and connected to a negative-phase output terminal of the modulation-current differential drive circuit, and a second resistor connected to a connection point of the cathode of the LD and the second inductance and connected to a positive-phase output terminal of the modulation-current differential drive circuit, and a positive-phase output terminal of the bias-current differential drive circuit is connected to the connection point.

Abstract: To enable optical line terminal to detect input disconnection of optical burst signal accurately in spite of changes of transmission rate of optical-burst signal received from optical network unit, OLT (optical line terminal) includes photo-detector for converting the optical-burst signal received to current signal; preamplifier for converting the current signal to voltage signal; input disconnection detecting circuit for comparing output amplitude of preamplifier with threshold, and for outputting input disconnection signal indicating disconnection of input of the optical-burst signal; and control circuit for controlling conversion gain of preamplifier in a manner that the conversion gain becomes conversion gain corresponding to the transmission rate of the optical-burst signal received, and for controlling input disconnection detecting circuit in a manner that it outputs the input disconnection signal in response to the threshold corresponding to the transmission rate of the optical-burst signal received.

Abstract: A laser diode drive circuit includes a laser diode (LD), a modulation-current differential drive circuit, a bias-current differential drive circuit, a first inductance connected between an anode of the LD and a positive power source, a second inductance connected between a cathode of the LD and a negative-phase output terminal of the bias-current differential drive circuit, a first resistor connected to a connection point of the anode of the LD and the first inductance and connected to a negative-phase output terminal of the modulation-current differential drive circuit, and a second resistor connected to a connection point of the cathode of the LD and the second inductance and connected to a positive-phase output terminal of the modulation-current differential drive circuit, and a positive-phase output terminal of the bias-current differential drive circuit is connected to the connection point.