Abstract: A technique for decreasing attenuation of emitted pulsed light with a pulse width of 2 ns or less is provided. A light emitting circuit configured to emit pulsed light includes a boosting block, a laser diode, a wiring, a charge capacitor with its end connected to the wiring, and a switching element configured to be turned on or off to apply voltage to the laser diode. The inductance of the wiring is not greater than 1.4 nH. The laser diode emits pulsed light with a pulse width of 2 ns or less.

Abstract: The invention provides a laser scanner system, which comprises a laser scanner which includes a distance measuring unit for receiving a reflection light of a distance measuring light from an object to be measured and performing a distance measurement, a scanning unit for rotatably irradiating the distance measuring light, a directional angle detecting unit for detecting an irradiating direction of the distance measuring light, a GNSS device, and a control arithmetic unit, wherein the laser scanner is installed at two points, and wherein the control arithmetic unit obtains global coordinates of installation positions of the laser scanner from the GNSS device respectively, scans the distance measuring light over a total circumference at each of the installation positions, acquires point cloud data of the total circumference, performs a shape matching of the two point cloud data and combines the two point cloud data.

Abstract: The invention provides a surveying instrument, which comprises a horizontal rotating unit, a measuring unit installed on the horizontal rotating unit, a coupler for mechanically coupling the horizontal rotating unit with the measuring unit, and a connector for electrically connecting the horizontal rotating unit with the measuring unit, wherein the coupler couples the horizontal rotating unit with the measuring unit and can separate from each other, the connector can electrically connect the horizontal rotating unit with the measuring unit and can separate from each other, wherein the horizontal rotating unit comprises a driving unit for rotating the measuring unit, a horizontal angle detector for detecting a horizontal angle, and a horizontal angle control unit for calculating horizontal angle data based on a signal from the horizontal angle detector and for controlling the driving unit, wherein the measuring unit comprises a distance measuring unit for performing a distance measurement, a vertical angle det

Abstract: A distance measuring device is provided at low cost. The distance measuring device includes an avalanche photodiode, a TIA, and damping circuits. The avalanche photodiode detects pulsed light that is reflected from an object to be measured. The TIA is an amplifier circuit that converts electric current output from the avalanche photodiode into a voltage signal. The damping circuits and are arranged in a rear stage of the TIA and convert pulse signals into signals with a damped oscillation waveform. The signal path from the avalanche photodiode to the TIA allows a direct current signal to pass therethrough.

Abstract: The invention provides a surveying instrument, which comprises a horizontal rotating unit and a measuring unit installed on the horizontal rotating unit, wherein the horizontal rotating unit comprises a driving unit for rotating the measuring unit, a horizontal angle detector for measuring horizontal angle data, a first synchronization data generating unit, a first storage unit and a first control unit, the first control unit associates the horizontal angle data with the first synchronization data and stores in the first storage unit, wherein the measuring unit comprises a distance measuring unit for performing a distance measurement, a vertical angle detector for detecting a vertical angle at a time of distance measurement, a second synchronization data generating unit, a second storage unit and a second control unit, the second synchronization data generating unit outputs second synchronization data which indicate timings of a time of acquisition of the distance measurement data and a time of acquisition of

Abstract: The invention provides a laser scanner system, which comprises a laser scanner which includes a distance measuring unit for emitting a distance measuring light, receiving a reflected light, and performing a distance measurement, a scanning unit for rotatably irradiating the distance measuring light, a directional angle detecting unit for detecting an irradiating direction of the distance measuring light, a GNSS device and a control arithmetic unit, and a target which sets a back sight point, wherein the control arithmetic unit has a target scanning mode and a point cloud data measurement mode, and is configured to calculate point cloud data with a global coordinate value and a global coordinate value of the target based on the global coordinate value obtained by the GNSS device, a measurement result obtained by executing the point cloud data measurement mode and a measurement result obtained by executing the target scanning mode.

Abstract: In order to achieve the dispersion of a processing load between communication devices that perform information transmission, an information communication system according to an exemplary aspect of the present invention includes a first transmission system configured to transmit information in a direction from a first communication device to a second communication device; and a second transmission system configured to transmit information in a direction opposite to the direction of the first transmission system, wherein part of transmission information is received as received information in each of the first transmission system and the second transmission system.

Abstract: The invention provides a laser light emitting device, which comprises a laser light emitter for emitting a pump light, a resonator for emitting a laser beam by oscillating and amplifying the pump light and a multi-mode fiber for guiding the pump light emitted from the laser light emitter to the resonator, wherein a mode scrambler is provided on the multi-mode fiber, the pump light propagating the multi-mode fiber is stirred and a light intensity distribution is unified by the mode scrambler, and the pump light is entered to the resonator.

Abstract: [Problem] It is to provide an optical receiving device, a control method and device of a photon detector, and a dark count evaluation method of the photon detector that make it possible to perform a dark count evaluation with the photon detector performing a receiving operation. [Solution] It is to include a Z pulse information detection unit 205 and a control unit 204 selectively extracting outputs of photon detectors PD1 and PD2 to a transmission light pulse with light intensity substantially equal to zero included in a transmission light pulse train and a dark count evaluation unit 206 evaluating dark counts of the photon detectors based on photon detection counts indicated by the extracted outputs.

Abstract: The invention provides a surveying instrument, which comprises a horizontal rotating unit, a measuring unit installed on the horizontal rotating unit, a coupler for mechanically coupling the horizontal rotating unit with the measuring unit, and a connector for electrically connecting the horizontal rotating unit with the measuring unit, wherein the coupler couples the horizontal rotating unit with the measuring unit and can separate from each other, the connector can electrically connect the horizontal rotating unit with the measuring unit and can separate from each other, wherein the horizontal rotating unit comprises a driving unit for rotating the measuring unit, a horizontal angle detector for detecting a horizontal angle, and a horizontal angle control unit for calculating horizontal angle data based on a signal from the horizontal angle detector and for controlling the driving unit, wherein the measuring unit comprises a distance measuring unit for performing a distance measurement, a vertical angle det

Abstract: The invention provides a surveying instrument, which comprises a horizontal rotating unit and a measuring unit installed on the horizontal rotating unit, wherein the horizontal rotating unit comprises a driving unit for rotating the measuring unit, a horizontal angle detector for measuring horizontal angle data, a first synchronization data generating unit, a first storage unit and a first control unit, wherein the first synchronization data generating unit outputs first synchronization data which indicate a timing at a time of acquisition of the horizontal angle data of the horizontal angle detector, the first control unit associates the horizontal angle data with the first synchronization data and stores in the first storage unit, wherein the measuring unit comprises a distance measuring unit for performing a distance measurement, a vertical angle detector for detecting a vertical angle at a time of distance measurement, a second synchronization data generating unit, a second storage unit and a second contr

Abstract: The invention provides a laser light emitting device, which comprises a laser light emitter for emitting a pump light, a resonator for emitting a laser beam by oscillating and amplifying the pump light and a multi-mode fiber for guiding the pump light emitted from the laser light emitter to the resonator, wherein a mode scrambler is provided on the multi-mode fiber, the pump light propagating the multi-mode fiber is stirred and a light intensity distribution is unified by the mode scrambler, and the pump light is entered to the resonator.

Abstract: A three-dimensional measuring device includes a light source unit, a light projecting optical unit, a light receiving optical unit, a light receiving element, a scanning unit, an angle detector, an illumination light source unit, an image pickup unit and a control arithmetic unit. The control arithmetic unit comprises a distance data processing unit for controlling the scanning unit, for calculating a distance to the object to be measured based on a received light signal, and for calculating a three-dimensional data of the object based on a calculated distance and a detection signal from the angle detector, and an image data processing unit for acquiring an illuminated image and an unilluminated image, for acquiring a difference image based on both images, for detecting a retroreflective target based on the difference image and a detected intensity of a reflected light from the difference image, and for calculating a position of the target.

Abstract: (Object) To provide an optical receiver and a control method thereof that enable equalization of both the quantum efficiencies and the dark count probabilities of multiple photon detectors. (Solving Means) An optical receiver includes multiple photon detectors, a first equalizing means that equalizes either dark count probabilities or quantum efficiencies of the multiple photon detectors, and a second equalizing means that equalizes the other ones without affecting the equalization by the first equalizing means.

Abstract: [Problem] It is to provide an optical receiving device, a control method and device of a photon detector, and a dark count evaluation method of the photon detector that make it possible to perform a dark count evaluation with the photon detector performing a receiving operation. [Solution] It is to include a Z pulse information detection unit 205 and a control unit 204 selectively extracting outputs of photon detectors PD1 and PD2 to a transmission light pulse with light intensity substantially equal to zero included in a transmission light pulse train and a dark count evaluation unit 206 evaluating dark counts of the photon detectors based on photon detection counts indicated by the extracted outputs.

Abstract: A laser scanner comprises a light projecting optical system for projecting a distance measuring light, a deflecting optical member for deflecting and projecting the distance measuring light to a measurement area, a distance measuring unit for carrying out measurement based on a reflection light and for acquiring distance data of the measurement area, a second image pickup unit capable of continuously acquiring image data including the measurement area, and a control unit. The control unit has a first image processing unit for acquiring a three-dimensional image based on the image data and on the distance data, and also has a second image processing unit for detecting a mobile object by comparing image data being adjacent to each other in terms of time. The control unit controls the distance measuring unit so that measurement of the mobile object detected in the measurement area is restricted by the second image processing unit.

Abstract: An electronic distance measuring instrument comprises a pulsed light emitting light source, means for creating a distance measuring pulsed light and an internal reference pulsed light, a photodetector for detecting the pulsed lights, and a measuring unit for calculating a distance to an object to be measured based on a photodetection signal. The measuring unit performs coarse distance measurement based on difference of photodetection time between the internal reference pulsed light and the distance measuring pulsed light, carries out Fourier function transform on photodetection waveform of the pulsed lights respectively, separates the waveforms to a plurality of frequency components, obtains phase difference for each of the frequency components acquired, performs fine distance measurement based on time difference acquired from phase difference, and measures a distance to the object by adding a result of coarse distance measurement to a result of fine distance measurement.

Abstract: A panoramic image preparing method comprises a step of setting a measurement range 70 so as to include objects to be measured 72, 73, and 74, a step of dividing the measurement range as required and setting two or more sections 71 and a step of synthesizing partial images 81 photographed for each of the sections and preparing a panoramic image 80, a step of photographing each of the sections under two or more image pickup conditions and a step of synthesizing the panoramic image by using the partial image photographed under an optimal image pickup condition at least about the object to be measured.

Abstract: A three-dimensional measuring device includes a light source unit, a light projecting optical unit, a light receiving optical unit, a light receiving element, a scanning unit, an angle detector, an illumination light source unit, an image pickup unit and a control arithmetic unit. The control arithmetic unit comprises a distance data processing unit for controlling the scanning unit, for calculating a distance to the object to be measured based on a received light signal, and for calculating a three-dimensional data of the object based on a calculated distance and a detection signal from the angle detector, and an image data processing unit for acquiring an illuminated image and an unilluminated image, for acquiring a difference image based on both images, for detecting a retroreflective target based on the difference image and a detected intensity of a reflected light from the difference image, and for calculating a position of the target.

Abstract: It is an object of the present invention to provide a network system for quantum key distribution (QKD) for free space and fiber networks. The system of the present invention generates a couple of photons which have different wavelength and inputs each of the photons into the asymmetric Mach-Zehnder interferometer to obtain time-bin entangled state. It provides polarization information with one part of the photons. Then it can obtain hybrid quantum entanglement. The system of the present invention may be used hybrid quantum key distribution system applied for both free space and fibers.