Omni-directional mirror system that measures the actual distance of objects

Abstract

The invention discloses an all-dimensional sight glass system capable of measuring the actual distance of an object. The all-dimensional sight glass system capable of measuring the actual distance of the object comprises a plane mirror, a camera, a display and a processing module. The plane mirror and the camera are both arranged outside a vehicle. The camera is fixedly arranged at the front end of the plane mirror and is opposite to the plane mirror. The distance between the camera and the plane mirror and the distance between the camera and a ground plane are fixed. The plane mirror is perpendicular to the ground plane. The display and the processing module are arranged inside the vehicle. The input end of the processing module is connected with the output end of the camera, and the output end of the processing module is connected with the input end of the display. The all-dimensional sight glass system capable of measuring the actual distance of the object can display all conditions outside the vehicle in an all-dimensional mode. The conditions outside the vehicle can be known without rear-view mirrors and various blind areas can be thoroughly solved while the vehicle is used, therefore, driving is much safer, the difficulty of driving is reduced, and thus the occurrence of road accidents is effectively reduced.

Description

technical field [0001] The invention relates to the field of automobile mirrors, in particular to an omnidirectional mirror system capable of measuring the actual distance of objects. Background technique [0002] In existing automobiles, three rearview mirrors are all provided with: interior rearview mirror, left rearview mirror, and right rearview mirror, for observing the rear position of the vehicle, wherein the rearview mirror in the car is mainly used for observing the front view of the vehicle. The rear is the position behind the rear windshield, while the left and right rearview mirrors are mainly used to observe the left and right rear positions of the vehicle. [0003] However, the interior rearview mirror, left rearview mirror, and right rearview mirror cannot fully observe the situation behind the vehicle. Within the range of 3 meters directly behind the rear of the car, the blind spots of the left and right rearview mirrors are outside the angle of 30°C with th...

AI Technical Summary

Problems solved by technology

[0003] However, the interior rearview mirror, left rearview mirror, and right rearview mirror cannot fully observe the situation behind the vehicle. Within the range of 3 meters directly behind the rear of the car, the blind spots of the left and right rearview mirrors are outside the angle of 30°C with the left and right doors; at the same time, due to the influence of the internal structure of the vehicle, the driver in the car cannot fully observe the outside of the car For example, the A-pillar, B-pillar, and C-pillar of the vehicle will block the driver's line of sight, and the range is relatively large. Therefore, even if the driver concentrates on driving, there is still a risk of accident. Existing cars are equipped with auxiliary equipment such as reversing radar, sonar system, and reversing camera, but the reversing radar and sonar system cannot see real-time images, and the detection range is generally within 2.5 meters, the effect is not obvious, and Although the reversing camera can observe the image, it cannot display the distance to the object. These auxiliary devices are generally only suitable for reversing and are not suitable for other blind spots. In addition, the driver needs to observe the interior rearview mirror and The left and right rearview mirrors make it impossible to focus on the driving conditions ahead, which can easily lead to traffic accidents

Images