Abstract: There is provided a surface abnormality detection device, and a system, capable of detecting an abnormal portion having a displacement below the distance measurement accuracy when detecting the abnormal portion on the surface of a structure. A surface abnormality detection device includes a classification means for classifying an object under measurement into one or more clusters having the same structure, based on position information at a plurality of points on a surface of the object under measurement; a determination means for determining a reflection brightness normal value of the cluster based on a distribution of reflection brightness values at a plurality of points on a surface of the cluster; and an identification means for identifying an abnormal portion on the surface of the cluster based on a difference between the reflection brightness normal value and the reflection brightness value at each of the plurality of points.

Abstract: To suppress the deterioration of the characteristics of a MIMO equalizer as well as minimizing an increase in circuit size in spite of the occurrence of signal spectrum narrowing and asymmetric spectrum degradation, a wavelength-division multiplexing optical transmission system (10) according to an embodiment includes a transmitter (1) that generates one channel signal by wavelength-division multiplexing a plurality of subcarrier signals so as to overlap each other and transmits the channel signal, and a receiver (2) that separates a received channel signal into subcarrier signals, and performs equalization using an MIMO equalizer (3) including a FDE-MIMO equalizer (4) and a TDE-MIMO equalizer (5) on each of the separated subcarrier signals.

Abstract: There is provided a surface abnormality detection device, and a system, capable of detecting an abnormal portion having a displacement below the distance measurement accuracy when detecting the abnormal portion on the surface of a structure. A surface abnormality detection device includes a classification means for classifying an object under measurement into one or more clusters having the same structure, based on position information at a plurality of points on a surface of the object under measurement; a determination means for determining a reflection brightness normal value of the cluster based on a distribution of reflection brightness values at a plurality of points on a surface of the cluster; and an identification means for identifying an abnormal portion on the surface of the cluster based on a difference between the reflection brightness normal value and the reflection brightness value at each of the plurality of points.

Abstract: Generation unit generates a plurality of transmission pulses, the plurality of transmission pulses being formed so that phases in a plurality of respective regions of the transmission pulse can be different from each other, and being formed so that a phase difference between the phases in the plurality of respective regions of the transmission pulse is changed according to a transmission order of the transmission pulses. Transmission unit repeatedly transmits the generated transmission pulses. Receiving unit receives reflected pulses of the transmission pulses reflected on a distance-measurement-target object. Detection unit detects a phase difference between phases in a plurality of respective regions of the received reflected pulse. Distance calculation unit calculates a distance to the distance-measurement-target object based on a receiving timing of the received reflected pulse and a transmitting timing of the transmission pulse corresponding to the phase difference detected from the reflected pulse.

Abstract: The generation unit (2) generates a transmission pulse set so that a time difference between times at which a plurality of transmission pulses are transmitted respectively differs according to the transmitting order of the transmission pulse set. A transmission unit (4) repeatedly transmits the generated transmission pulse set. A reception unit (6) receives reflected pulses of the transmission pulses reflected on a distance-measurement-target object. A specification unit (8) specifies a time difference between times at which a plurality of received reflected pulses are received. A distance calculation unit (10) calculates a distance to the distance-measurement-target object based on a receiving timing of the received reflected pulse and a transmitting timing of the transmission pulse corresponding to the time difference specified for the reflected pulse.

Abstract: A generation unit (2) generates a plurality of transmission pulses of which the strength of an optical signal changes in a pulse-like manner. Note that the generation part (2) generates a plurality of transmission pulses having frequency offsets different from each other. The transmission unit (4) repeatedly transmits transmission pulses generated by the generation unit (2). The reception part (6) receives reflected pulses of the respective transmission pulses reflected on a distance-measurement-target object. The detection unit (8) detects the frequency offsets of the reflected pulses received by the reception unit (6). The distance calculation unit (10) calculates a distance to the distance-measurement-target object based on the receiving timings of the reflected pulses received by the reception unit (6) and the transmitting timings of the transmission pulses corresponding to the frequency offsets detected from the reflected pulses.

Abstract: A monitoring control device (1) according to the present embodiment is, for example, a monitoring control device used in a monitoring system that monitors a monitoring target facility by using a distance measurement sensor (5). The monitoring control device (1) includes: a sensing region acquisition unit (3) configured to acquire measurement data indicating a sensing region of the distance measurement sensor (5) provided in order to monitor a monitoring target facility; and a management unit (4) configured to identify a non-monitoring region of the monitoring target facility, based on the sensing region and position data of the distance measurement sensor (5).

Abstract: A light irradiating means irradiates a plurality of lights emitted from a plurality of light sources to an area to be monitored. The light irradiating means irradiates at least one of the plurality of lights and at least another one of the plurality of lights to the area to be monitored with mutually different beam diameters. A light reception means receives reflected lights of the plurality of lights incident from the area to be monitored. A distance measuring means measures, for each of the plurality of lights, the distance to an object present in the area to be monitored based on the reflected lights. A feature extracting means extracts a feature of the object present in the area to be monitored based on results of measurement of the distance for the plurality of lights.

Abstract: A distance-measuring apparatus (2000) generates transmission light by generating a distance measurement signal, and subjecting an optical carrier wave to quadrature modulation on the basis of the generated distance measurement signal. The distance-measuring apparatus (2001) outputs transmission light, and receives reflected light generated by reflecting the transmission light on an object (10) to be measured. The distance-measuring apparatus (2000) compares the received reflected light with reference light to compute a distance from the distance-measuring apparatus (2000) to the object (10) to be measured.

Abstract: A range finding apparatus (2000) generates a plurality of range finding signals. The range finding apparatus (2000) generates transmission light acquired by performing at least one of quadrature modulation and polarization modulation on an optical carrier wave by using each of the generated range finding signals. The range finding apparatus (2000) transmits the generated transmission light. The range finding apparatus (2000) receives reflection light which is the transmission light reflected by an object to be measured. The range finding apparatus (2000) extracts a reception signal corresponding to each of the range finding signals by demodulating the reflection light.

Abstract: A distance measurement device (2000) generates transmission light by modulating an optical carrier wave. The distance measurement device (2000) transmits the generated transmission light, and receives reflected light acquired by the transmission light being reflected by a measured object (10). The distance measurement device (2000) generates a first beat signal by causing the transmission light to interfere with reference light. The distance measurement device (2000) generates a second beat signal by causing the reflected light to interfere with the reference light. The distance measurement device (2000) calculates a distance to the measured object (10), based on a difference between the first beat signal and the second beat signal.

Abstract: The receiving-side system (10) includes a smaller number of optical reception front ends (12) than the number of a plurality of wavelength-multiplexed subcarrier signals. Each of the optical reception front ends (12) is configured to receive two or a plurality subcarrier signals of the plurality of subcarrier signals. A frequency offset monitoring unit (22) monitors frequency offsets of the respective subcarrier signals received by the optical reception front end (12). A light source frequency control unit (24) controls at least one of a light source frequency of the transmitting-side system (2) and a light source frequency of the receiving-side system (10) based on a result of the monitoring performed by the frequency offset monitoring unit (22).

Abstract: A distance measurement apparatus comprises a distance measurement optical signal generation part, a collimating part, a beam diameter change part, an emission direction control part, and a beam diameter change control part. The distance measurement optical signal generation part generates an optical signal for measuring the distance to a target. The collimating part collimates the optical signal. The beam diameter change part is able to change a beam diameter of the collimated light. The emission direction control part controls an emission destination of the collimated light with the diameter changed. The beam diameter change control part controls the changing of the beam diameter by the beam diameter change part according to the emission direction of an outgoing.

Abstract: A reception device 20 is configured to include a separation means 21 and a plurality of optical reception means 22. Each optical reception means 22 is configured to further include an optical/electrical conversion means 23 and a band restoration means 24. The separation means 21 separates a multiplexed signal into which signals of respective channels to which spectral shaping that narrows bandwidth to less than or equal to a baud rate is applied are multiplexed at spacings less than or equal to the baud rate on the transmission side into optical signals for the respective channels. Each optical/electrical conversion means 23 converts an optical signal to an electrical signal as a reception signal. Each band restoration means 24 applies processing having inverse characteristics to those of the band narrowing filter processing to the reception signal and restores the band of the reception signal.

Abstract: A reception device 20 is configured to include a separation means 21 and a plurality of optical reception means 22. Each optical reception means 22 further includes an optical/electrical conversion means 23, a reception coefficient computation means 24, and a band restoration means 25. The separation means 21 separates a multiplexed signal into which signals of respective channels to which spectral shaping that narrows bandwidth to less than or equal to a baud rate is applied as band narrowing filter processing on the transmission side, based on characteristics of a transmission line are multiplexed at spacings less than or equal to the baud rate. Each band restoration means 25 applies processing having inverse characteristics to those of the band narrowing filter processing to a reception signal, based on the band narrowing parameter acquired by the reception coefficient computation means 24 and thereby restores the band of the reception signal.

Abstract: In order to enable flexible and efficient operations according to various electric power circumstances, a digital optical communication system 1 is provided with multiple optical transfer apparatuses 2, 3 and a communication control unit 4. The optical transfer apparatuses 2, 3 respectively house optical transmission/reception devices 10, 20 each including a reception-side waveform equalization processing unit 12 and a transmission-side waveform equalization processing unit 11 that perform, respectively on the reception side and on the transmission side, equalization processing for compensating waveform distortion that occurs on transfer paths 5, 6.

Abstract: A reception device 20 is configured to include a separation means 21 and a plurality of optical reception means 22. Each optical reception means 22 further includes an optical/electrical conversion means 23, a reception coefficient computation means 24, and a band restoration means 25. The separation means 21 separates a multiplexed signal into which signals of respective channels to which spectral shaping that narrows bandwidth to less than or equal to a baud rate is applied as band narrowing filter processing on the transmission side, based on characteristics of a transmission line are multiplexed at spacings less than or equal to the baud rate. Each band restoration means 25 applies processing having inverse characteristics to those of the band narrowing filter processing to a reception signal, based on the band narrowing parameter acquired by the reception coefficient computation means 24 and thereby restores the band of the reception signal.

Abstract: The receiving-side system (10) includes a smaller number of optical reception front ends (12) than the number of a plurality of wavelength-multiplexed subcarrier signals. Each of the optical reception front ends (12) is configured to receive two or a plurality subcarrier signals of the plurality of subcarrier signals. A frequency offset monitoring unit (22) monitors frequency offsets of the respective subcarrier signals received by the optical reception front end (12). A light source frequency control unit (24) controls at least one of a light source frequency of the transmitting-side system (2) and a light source frequency of the receiving-side system (10) based on a result of the monitoring performed by the frequency offset monitoring unit (22).

Abstract: A reception device 20 is configured to include a separation means 21 and a plurality of optical reception means 22. Each optical reception means 22 is configured to further include an optical/electrical conversion means 23 and a band restoration means 24. The separation means 21 separates a multiplexed signal into which signals of respective channels to which spectral shaping that narrows bandwidth to less than or equal to a baud rate is applied are multiplexed at spacings less than or equal to the baud rate on the transmission side into optical signals for the respective channels. Each optical/electrical conversion means 23 converts an optical signal to an electrical signal as a reception signal. Each band restoration means 24 applies processing having inverse characteristics to those of the band narrowing filter processing to the reception signal and restores the band of the reception signal.

Abstract: A digital optical receiver capable of adaptively correcting the linearity of an analog front end unit is provided.