Abstract: Problems occurring due to a difference in point of view between cameras in compositing a panoramic image by using multiple images taken by the cameras are solved. An image processing device includes an image data receiving unit 101, a panoramic image generating unit 102, a designation receiving unit 103, and a single photographic image selecting unit 105. The image data receiving unit 101 receives data of a first still image and a second still image. The panoramic image generating unit 102 projects the first still image and the second still image on a projection sphere to generate a composited image. The designation receiving unit 103 receives designation of a specific position in the panoramic image. The single photographic image selecting unit 105 selects one of the first still image and the second still image, which contains the designated position received by the designation receiving unit 103.

Abstract: Exterior orientation parameters of a camera are easily determined by, for example, a reference image being obtained by photographing a building 131 with a camera 112, in which exterior orientation parameters are determined, while a vehicle 100 travels, and a comparative image being simultaneously obtained by photographing the building 131 with a camera 113, in which exterior orientation parameters are undetermined. Then, points that match between the reference image and the comparative image are selected, and relative orientation and scale adjustment using a predetermined scale are performed, whereby the exterior orientation parameters of the camera 113 are calculated.

Abstract: To carry out evaluation of a road surface property easily and in a short period of time without being costly. Measurement data of a road surface measured for a predetermined road width along a path of a road to be measured is acquired; a unit area having a preset length dimension along the path in the road width is set along the path; a model plane in the unit area is set based on the measurement data at each point in the unit area; point group data is generated from a spaced amount of the model plane and each point in the unit area, visualize and display the spaced amount in the path, and display a result of evaluation obtained through statistical processing with the path shown on a map.

Abstract: To rapidly and reliably measure a road surface property using measurement results and determination results of a road surface in the past. A vehicle mounted with a road surface property acquiring device is guided to a specified point on a road and measurement is carried out. The past road surface data on a past road surface property is acquired, a present position of the vehicle is acquired, and a past road surface property image representing a feature amount of the road surface property in a range including the present position created based on the past road surface data is displayed; and the vehicle is guided from the present position to a specified area while measuring a state of the road surface with the road surface property acquiring device.

Abstract: To efficiently and effectively display a plurality of pieces of information that can be acquired from measurement data.

Abstract: A technique for performing calibration of a laser scanner efficiently is provided. Point cloud position data of a building 131 is obtained by a laser scanner 141 in which exterior orientation parameters are already known. On the other hand, the building 131 is scanned by a laser scanner 115 while a vehicle 100 travels, and point cloud position data of the building 131 measured by the laser scanner 115 is obtained based on a trajectory the vehicle 100 has traveled. Then, exterior orientation parameters of the laser scanner 115 are calculated based on a correspondence relationship between these two point cloud position data.

Abstract: Deviations in a panoramic image obtained by compositing multiple images are corrected. An image processing device includes an image data receiving unit, a selection receiving unit, a three-dimensional position obtaining unit, a projection sphere setting unit, and a composited image generating unit. The image data receiving unit receives data of multiple still images, which are taken from different viewpoints and contain the same object. The selection receiving unit receives selection of a specific position of the object. The three-dimensional position obtaining unit obtains data of a three-dimensional position of the selected position. The projection sphere setting unit calculates a radius “R” based on the three-dimensional position of the selected position and sets a projection sphere having the radius “R”. The composited image generating unit projects the multiple still images on the projection sphere and thereby generates a composited image.

Abstract: A technique for preventing decrease in positioning precision due to reflected waves from a navigation satellite that is blocked by an obstacle in a positioning technique using a GNSS is provided. A navigation signal processing device includes a data obtaining unit 121, an elevation angle mask setting unit 125, and a point cloud position data obtaining unit 123. The data obtaining unit 121 performs positioning based on navigation signals from navigation satellites. The elevation angle mask setting unit 125 sets a condition for restricting utilization of the navigation signals from a specific navigation satellite. The point cloud position data obtaining unit 123 obtains three-dimensional point cloud position data of the surroundings of an antenna that receives the navigation signals. The elevation angle mask setting unit 125 sets the condition based on the three-dimensional point cloud position data.

Abstract: Detection of sunlight as noise is avoided in obtaining point clouds by using a laser scanner. A laser scanner controlling device includes a sun direction calculating unit 115, a brightness measuring unit 116, and a scan condition setting unit 118. The sun direction calculating unit 115 calculates the direction of the sun. The brightness measuring unit 116 measures the brightness of an image that contains the direction of the sun. The scan condition setting unit 118 sets a condition for restricting laser scanning in the direction of the sun when the brightness is not less than a predetermined threshold value.

Abstract: A technique is disclosed for easily performing calibration of a camera by using a MMS. A calibration device for a camera that is configured to photograph the sun includes an in-image sun position identifying unit 115, a sun position estimating unit 113, and a camera attitude calculating unit 116. The in-image sun position identifying unit 115 identifies a position of the sun in an image that is photographed by the camera. The sun position estimating unit 113 estimates a position of the sun in the image based on orbital information of the sun. The camera attitude calculating unit 116 calculates attitude of the camera based on differences between identified positions and the estimated positions of the sun in the images.

Abstract: A measuring instrument comprises an spherical camera (8) for acquiring image data over total circumference, a laser scanner (6, 7) installed integrally with the spherical camera and for acquiring point cloud data of the surroundings, a synchronous control unit (9) for controlling acquisition of data of the spherical camera and the laser scanner, a storage unit (12) for recording the image data and the point cloud data, an absolute scale acquiring means for acquiring an absolute scale for obtaining an absolute position of when images are photographed by the spherical camera, and a control arithmetic unit (10), wherein the control arithmetic unit calculates a 3D model based on the image data, the point cloud data, and the absolute position.

Abstract: A technique for efficiently calibrating a camera is provided. Reference laser scan data is obtained by scanning a building 131 by a laser scanner 115, which is fixed on a vehicle 100 and has known exterior orientation parameters, while the vehicle 100 travels. An image of the building 131 is photographed at a predetermined timing by an onboard camera 113. Reference point cloud position data, in which the reference laser scan data is described in a coordinate system defined on the vehicle 100 at the predetermined timing, is calculated based on the trajectory the vehicle 100 has traveled. Matching points are selected between feature points in the reference point cloud position data and in the image. Exterior orientation parameters of the camera 113 are calculated based on relative relationships between the reference point cloud position data and image coordinate values in the image of the matching points.

Abstract: Exterior orientation parameters of a camera are easily determined by, for example, a reference image being obtained by photographing a building 131 with a camera 112, in which exterior orientation parameters are determined, while a vehicle 100 travels, and a comparative image being simultaneously obtained by photographing the building 131 with a camera 113, in which exterior orientation parameters are undetermined. Then, points that match between the reference image and the comparative image are selected, and relative orientation and scale adjustment using a predetermined scale are performed, whereby the exterior orientation parameters of the camera 113 are calculated.

Abstract: The position and the attitude of a device or a member are determined. A camera 115, in which exterior orientation parameters are not determined, is photographed by a camera 113, in which exterior orientation parameters in an IMU coordinate system are determined. The camera 115 is rotatable around a shaft, in which the direction of the rotational shaft is preliminarily set, and a distance between the camera 113 and the camera 115 is known. In this condition, by analyzing the image of the camera 115 photographed by the camera 113, the exterior orientation parameters of the camera 115 are calculated.

Abstract: A technique for performing calibration of a laser scanner efficiently is provided. Point cloud position data of a building 131 is obtained by a laser scanner 141 in which exterior orientation parameters are already known. On the other hand, the building 131 is scanned by a laser scanner 115 while a vehicle 100 travels, and point cloud position data of the building 131 measured by the laser scanner 115 is obtained based on a trajectory the vehicle 100 has traveled. Then, exterior orientation parameters of the laser scanner 115 are calculated based on a correspondence relationship between these two point cloud position data.

Abstract: A measuring instrument comprises an spherical camera (8) for acquiring image data over total circumference, a laser scanner (6, 7) installed integrally with the spherical camera and for acquiring point cloud data of the surroundings, a synchronous control unit (9) for controlling acquisition of data of the spherical camera and the laser scanner, a storage unit (12) for recording the image data and the point cloud data, an absolute scale acquiring means for acquiring an absolute scale for obtaining an absolute position of when images are photographed by the spherical camera, and a control arithmetic unit (10), wherein the control arithmetic unit calculates a 3D model based on the image data, the point cloud data, and the absolute position.

Abstract: The invention provides a measuring method for installing a measuring rod 6 in a predetermined relation with respect to a coordinate system set to a mobile object 1, for transcribing a predetermined position of the measuring rod on a ground surface where the mobile object is set, for transcribing a measuring point of an object to be measured as set on the mobile object to the ground surface, for measuring a distance on the ground surface between the transcribed predetermined position and the transcribed measuring point, for obtaining a relation between the measuring point and the measuring rod on the ground based on a result of distance measurement, and for obtaining a position on a horizontal coordinate plane in the coordinate system of the measuring point based on the obtained relation and on the relation with the measuring rod with respect to the coordinate system, and the invention also provides a method for measuring a vertical distance between the predetermined position and the ground surface and a verti

Abstract: A laser scanner measuring system is disclosed, which has a laser scanner and a calibration target. The laser scanner comprises a light emitting element for emitting a pulsed laser beam, a rotary projecting unit for projecting the pulsed laser beam, a distance measuring unit, and a control unit for driving and controlling the light emitting element and the distance measuring unit. The calibration target has a reflection sector with a known shape and with high reflectance and is installed at a known position. In use, there is a step for judging a reflected pulsed laser beam from the reflection sector by detecting a level of light quantity, a step for determining a center position of the reflection sector based on the result of the judgment, and a step for calibrating the laser scanner measuring system based on the determined center position and on the known position.

Abstract: According to the present invention, a laser scanner measuring system, which has a laser scanner and a calibration target, wherein the laser scanner comprises a light emitting element for emitting a pulsed laser beam, a rotary projecting unit for projecting the pulsed laser beam for scanning, a distance measuring unit, which has a distance measuring light receiving unit, for measuring a distance by receiving a reflection light from an object to be measured, and a control unit for driving and controlling the light emitting element and the distance measuring unit, and wherein the calibration target has a reflection sector with a known shape and with high reflectance and is installed at a known position, comprising a step for judging a reflected pulsed laser beam from the reflection sector as received by the distance measuring light receiving unit by detecting a level of light quantity, a step for determining a center position of the reflection sector based on the result of the judgment, and a step for calibratin

Abstract: A laser scanner measuring system is disclosed, which has a laser scanner and a calibration target. The laser scanner comprises a light emitting element for emitting a pulsed laser beam, a rotary projecting unit for projecting the pulsed laser beam, a distance measuring unit, and a control unit for driving and controlling the light emitting element and the distance measuring unit. The calibration target has a reflection sector with a known shape and with high reflectance and is installed at a known position. In use, there is a step for judging a reflected pulsed laser beam from the reflection sector by detecting a level of light quantity, a step for determining a center position of the reflection sector based on the result of the judgment, and a step for calibrating the laser scanner measuring system based on the determined center position and on the known position.