A parking assist system for a vehicle includes a camera disposed at a vehicle and having a field of view exterior of the vehicle. An image processor processes image data captured by the camera to determine presence of a wall or object present in the field of view of the camera. A light projecting device is disposed at the vehicle and operable to project a visual pattern toward an area encompassed by the field of view of the camera. During a parking maneuver, and responsive to determination that the vehicle is approaching the wall or object, the parking assist system controls the light projecting device to project the visual pattern toward the determined wall or object. The projected visual pattern is viewable by a driver of the vehicle during the parking maneuver, and the projected visual pattern is indicative of distance between the vehicle and the determined wall or object.

A parking assist system for a vehicle includes a camera disposed at a vehicle and having a field of view exterior of the vehicle. An image processor processes image data captured by the camera to determine presence of a wall or object present in the field of view of the camera. A light projecting device is disposed at the vehicle and operable to project a visual pattern toward an area encompassed by the field of view of the camera. During a parking maneuver, and responsive to determination that the vehicle is approaching the wall or object, the parking assist system controls the light projecting device to project the visual pattern toward the determined wall or object. The projected visual pattern is viewable by a driver of the vehicle during the parking maneuver, and the projected visual pattern is indicative of distance between the vehicle and the determined wall or object.

A laser rangefinder with magnetic suction includes a first shell, a second shell, a display screen, a control button, a laser ranging device and a magnet device used to fix the laser rangefinder on a metal frame by magnetic suction. A front end of the first shell is provided with the display screen and the control button, a first accommodating cavity is formed between the first shell and the second shell, the laser ranging device is disposed in the first accommodating cavity, and the magnet device is disposed on the second shell. In this case, the laser rangefinder with magnetic suction makes the measurement more convenient and ensures the accuracy of the measurement results.

A laser rangefinder with magnetic suction includes a first shell, a second shell, a display screen, a control button, a laser ranging device and a magnet device used to fix the laser rangefinder on a metal frame by magnetic suction. A front end of the first shell is provided with the display screen and the control button, a first accommodating cavity is formed between the first shell and the second shell, the laser ranging device is disposed in the first accommodating cavity, and the magnet device is disposed on the second shell. In this case, the laser rangefinder with magnetic suction makes the measurement more convenient and ensures the accuracy of the measurement results.

A method interactively displays panoramic images of a scene. The method includes measuring 3D coordinates with a 3D measuring instrument at a first position and a second position. The 3D coordinates are registering into a common frame of reference. Within the scene, a trajectory includes a plurality of trajectory points. Along the trajectory, 2D images are generated from the commonly registered 3D coordinates. A trajectory display mode sequentially displays a collection of 2D images at the trajectory points. A rotational display mode allows a user to select a desired view direction at a given trajectory point. The user selects the trajectory display mode or the rotational display mode and sees the result shown on the display device.

A method interactively displays panoramic images of a scene. The method includes measuring 3D coordinates with a 3D measuring instrument at a first position and a second position. The 3D coordinates are registering into a common frame of reference. Within the scene, a trajectory includes a plurality of trajectory points. Along the trajectory, 2D images are generated from the commonly registered 3D coordinates. A trajectory display mode sequentially displays a collection of 2D images at the trajectory points. A rotational display mode allows a user to select a desired view direction at a given trajectory point. The user selects the trajectory display mode or the rotational display mode and sees the result shown on the display device.

The present application generally relates communications and hazard avoidance within a monitored driving environment. More specifically, the application teaches a system for improved target object detection in a vehicle equipped with a laser detection and ranging LIDAR system by determining a plurality of ranges in response to a plurality of light pulse reflections and determining a false target indication by exploiting the expected continuity of surfaces in the environment.

The present application generally relates communications and hazard avoidance within a monitored driving environment. More specifically, the application teaches a system for improved target object detection in a vehicle equipped with a laser detection and ranging LIDAR system by determining a plurality of ranges in response to a plurality of light pulse reflections and determining a false target indication by exploiting the expected continuity of surfaces in the environment.

A surveying instrument comprises a monopod installed on a reference point, a surveying instrument main body provided at a known distance from a lower end of the monopod and at a known angle with respect to an axis of the monopod and having a reference optical axis, wherein the surveying instrument main body performs an image pickup of an object to be measured and scans the object to be measured by a closed loop scan pattern respectively at a pre-rotation and a post-rotation of the surveying instrument main body, obtains cross points of a locus of a scan pattern of the pre-rotation and the post-rotation, obtains deflection angles of the cross point with respect to the reference optical axis of the pre-rotation and the post-rotation, and calculates a rotation angle of the surveying instrument main body based on a deviation between both of the deflection angles.

A surveying instrument comprises a monopod installed on a reference point, a surveying instrument main body provided at a known distance from a lower end of the monopod and at a known angle with respect to an axis of the monopod and having a reference optical axis, wherein the surveying instrument main body performs an image pickup of an object to be measured and scans the object to be measured by a closed loop scan pattern respectively at a pre-rotation and a post-rotation of the surveying instrument main body, obtains cross points of a locus of a scan pattern of the pre-rotation and the post-rotation, obtains deflection angles of the cross point with respect to the reference optical axis of the pre-rotation and the post-rotation, and calculates a rotation angle of the surveying instrument main body based on a deviation between both of the deflection angles.