CN218998126U - High-definition low-delay 3D wireless remote image transmission system - Google Patents

Abstract

A high-definition low-delay 3D wireless remote image transmission system relates to an improvement of a 3D wireless remote image transmission system, in particular to an improvement of a high-definition low-delay 3D wireless remote image transmission system. The device comprises a collection end, an infinite emission module, an emission end, a remote transmission module and a receiving end; the acquisition end is connected to the transmitting end through an infinite transmitting module, and the transmitting end is connected to the receiving end through a remote transmission module; the image information acquired by the acquisition end is transmitted to the transmitting end through the infinite transmitting module, the transmitting end receives the image information acquired by the acquisition end and transmits the image information to the receiving end, and the receiving end receives and stores the image information from the transmitting end; the receiving end comprises an acquisition module and an imaging module, the acquisition module acquires a depth image for correction, and the corrected image is displayed and imaged by the imaging module. The remote, low-delay and spatial position sensing capability is realized, the picture is clearer, and the wireless transmission distance is long.

Description

High-definition low-delay 3D wireless remote image transmission system

Technical Field

The utility model relates to an improvement of a 3D wireless remote image transmission system, in particular to an improvement of a high-definition low-delay 3D wireless remote image transmission system.

Background

The 3D wireless remote image transmission system mainly comprises a 3D camera and 3D display equipment. At present, 3D display technology is mature, IMAX 3D and other high-definition stereoscopic film playing technologies are popularized, various household stereoscopic playing devices such as 3D televisions and 3D projectors become household appliances purchased by common public, and the trend of replacing traditional film and television playing devices is greatly promoted.

In the prior art, when remote image transmission is performed, two-dimensional images can be transmitted mostly, a large number of coaxial cables are adopted as media of the image transmission system, network cables and optical fiber ring networks are adopted as high-definition image transmission systems of video transmission routes, but the image transmission systems have great disadvantages in the aspects of remote transmission, video information processing, special environment application and the like, such as large transmission delay, short transmission distance and unclear images.

Disclosure of Invention

The utility model aims at overcoming the defects and shortcomings of the prior art, and provides a high-definition low-delay 3D wireless remote image transmission system, wherein image pickup is mainly used for simulating an imaging process of human eyes. When shooting, two cameras are used for respectively shooting two-dimensional images with left and right visual angles, and a certain technical means is adopted when receiving, so that the left eye of a spectator can only see the picture of the left camera, the right eye can only see the picture of the right camera, and the two pictures generate stereoscopic depth after being fused by brains. In addition, the transmission process can support networking of a 5G video monitoring system, and in the monitoring process, high-definition videos are transmitted through wireless relay, so that the technical effects of high bandwidth, low loss and low delay are achieved.

In order to achieve the above purpose, the utility model adopts the following technical scheme: a high-definition low-delay 3D wireless remote image transmission system is characterized in that: the wireless transmitter comprises a collecting end 1, a wireless transmitting module 2, a transmitting end 3, a remote transmission module 4 and a receiving end 5; the acquisition end 1 is connected to the transmitting end 3 through the wireless transmitting module 2, and the transmitting end 3 is connected to the receiving end 5 through the remote transmission module 4; the acquisition end 1 acquires image information and transmits the image information to the transmitting end 3 through the wireless transmitting module 2, the transmitting end 3 receives the image information acquired by the acquisition end 1, the image information and the built-in basic verification information are transmitted to the receiving end 5 through the remote transmitting module 4, and the receiving end 5 receives and stores the image information from the transmitting end 3; the receiving end (5) comprises an acquisition module (51) and an imaging module (52), and the acquisition module (51) acquires image information and transmits the image information to the imaging module (52).

The acquisition module 51 comprises a left receiver 511 and a right receiver 512, i.e. the left receiver 511 receives the image transmitted by the left transmitter 31 and the right receiver 512 receives the image transmitted by the right transmitter 32. The corresponding receiver receives the transmitted image information transmitted by the corresponding transmitter 31, prevents inter-code crosstalk, avoids the situation of image distortion, and ensures the high definition of the image to the maximum extent.

The double-picture fusion is performed on the imaging module 52, and finally the double-picture fusion is presented on the viewing mirror 521, and the received image is processed on the imaging module 52, so that the image source information of the image in the transmission process is corrected, and the poor spatial perception capability of the image in the transmission process is avoided.

The acquisition end 1 comprises a left Gao Qingxiang camera 11 and a right high-definition camera 12, wherein the left high-definition camera 11 acquires a left real object image, and the right high-definition camera acquires a right high-definition image. The method is beneficial to the omnibearing collection of the whole object, and can display the image source information more accurately in the process of synthesizing the final image.

The wireless transmitting module 2 and the remote transmission module 4 are respectively internally provided with 5G communication units. The 5G network is adopted for transmission, so that the phenomenon of difficult sending and receiving in the transmission process due to the influence of terrains or various external factors is avoided.

The acquisition end 1 adopts a high-definition camera to acquire images, the transmitting end 3 adopts a transmitter to transmit the images, and the receiving end 5 adopts 3D glasses to receive and display the images. After the high-definition camera acquires the image, the image is directly transmitted to the transmitter, the transmitter directly transmits the image information to the receiver, the receiver is arranged on the glasses, and a viewer can see the 3D stereogram conveniently by using the glasses.

The transmitting end 3 and the receiving end 5 are provided with the monitoring terminal 33, the monitoring terminal 33 monitors the communication transmission of the image, the monitoring terminal 33 monitors, the real-time control of the image in the two wireless transmission processes by a monitor is ensured, and the maintenance of the module unit is facilitated.

The working principle of the utility model is as follows: when the image capturing device is used, in the shooting process, the left high-definition camera 11 and the right high-definition camera 12 of the acquisition end 1 are utilized to acquire images of objects, the wireless transmission module 2 is utilized to transmit image information to the transmission end 3 in real time, and for a manager at the near end, the image information can be checked in real time by monitoring the terminal with the image acquisition wireless transmission module 2, so that the image information checked by the manager in a low-delay and low-loss state is convenient, and then the response to an emergency condition is fast; meanwhile, after the transmitting end 3 receives the image information acquired by the image acquisition end 1, the image information is transmitted to the receiving end 5 by utilizing the remote transmission module 4, and the monitoring terminal of the receiving end is convenient for a manager at the far end to carry out remote monitoring, and finally the image information is received by the receiving end 5 and is presented by the rear view mirror after being received.

After the technical scheme is adopted, the utility model has the beneficial effects that: the real-time wireless transmission of the 3D stereoscopic space picture realizes real-time low-delay transmission of the 3D stereoscopic space picture, is the remote space sensing capability of an image receiver, better judges the spatial position relationship, is similar to everything seen by two eyes of a human, and has the advantages of space position sensing capability, clearer picture, long wireless transmission distance and the like for the wireless image transmission system in the prior art.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a transmission schematic diagram of a high-definition low-latency 3D wireless remote image transmission system;

FIG. 2 is a schematic image of a high-definition low-latency 3D wireless remote image-transmission system;

FIG. 3 is a transmission flow chart of a high-definition low-delay 3D wireless remote image transmission system;

reference numerals illustrate: acquisition end 1, left high definition camera 11, right high definition camera 12, wireless transmitting module 2, transmitting end 3, left transmitter 31, right transmitter 32, monitor terminal 33, remote transmission module 4, receiving end 5, acquisition module 51, left receiver 511, right receiver 512, imaging module 52, view mirror 521.

Detailed Description

Referring to fig. 1-3, the technical scheme adopted in the specific embodiment is as follows: the wireless transmitter comprises a collecting end 1, a wireless transmitting module 2, a transmitting end 3, a remote transmission module 4 and a receiving end 5; the acquisition end 1 is connected to the transmitting end 3 through the wireless transmitting module 2, the transmitting end 3 is connected with the receiving end 5 through the remote transmitting module 4, the image information acquired by the acquisition end 1 is transmitted to the transmitting end 3 through the wireless transmitting module 2, the image information acquired by the acquisition end 1 is received by the transmitting end 3, the image information and the built-in basic verification information are transmitted to the receiving end 5 through the remote transmitting module 4, and the receiving end 5 receives and stores the image information from the transmitting end 3; the acquisition end 1 comprises a left Gao Qingxiang camera 11 and a right high-definition camera 12, wherein the left high-definition camera 11 acquires a left real object image, and the right high-definition camera acquires a right high-definition image. The method is beneficial to the omnibearing collection of the whole object, and can display the image source information more accurately in the process of synthesizing the final image. The wireless transmitting module 2 and the remote transmitting module 4 are respectively internally provided with 5G communication units. The 5G network is adopted for transmission, so that the phenomenon of difficult sending and receiving in the transmission process due to the influence of terrains or various external factors is avoided. The acquisition end 1 adopts a high-definition camera to acquire images, the transmitting end 3 adopts a transmitter to transmit the images, and the receiving end 5 adopts 3D glasses to receive and display the images. After the high-definition camera acquires the image, the image is directly transmitted to the transmitter, the transmitter directly transmits the image information to the receiver, the receiver is arranged on the glasses, and a viewer can see the 3D stereogram conveniently by using the glasses. The transmitting end 3 and the receiving end 5 are provided with the monitoring terminal 33, the monitoring terminal 33 monitors the communication transmission of the image, the monitoring terminal 33 monitors, the real-time control of the image in the two wireless transmission processes by a monitor is ensured, and the maintenance of the module unit is facilitated.

The double-picture fusion is performed on the imaging module 52, and finally the double-picture fusion is presented on the viewing mirror 521, and the received image is processed on the imaging module 52, so that the image source information of the image in the transmission process is corrected, and the poor spatial perception capability of the image in the transmission process is avoided. The receiving end 5 comprises an acquisition module 51 and an imaging module 52, the acquisition module 51 acquires a depth image for correction, and the corrected image is displayed and imaged by the imaging module 52. The acquisition module 51 comprises a left receiver 511 and a right receiver 512, i.e. the left receiver 511 receives the image transmitted by the left transmitter 31 and the right receiver 512 receives the image transmitted by the right transmitter 32. The corresponding receiver receives the transmitted image information transmitted by the corresponding transmitter 31, prevents inter-code crosstalk, avoids the situation of image distortion, and ensures the high definition of the image to the maximum extent.

The foregoing is merely illustrative of the present utility model and not restrictive, and other modifications and equivalents thereof may occur to those skilled in the art without departing from the spirit and scope of the present utility model.

Claims (7)

1. A high-definition low-delay 3D wireless remote image transmission system is characterized in that: the wireless transmitter comprises a collecting end (1), a wireless transmitting module (2), a transmitting end (3), a remote transmission module (4) and a receiving end (5); the acquisition end (1) is connected to the transmitting end (3) through the wireless transmitting module (2), and the transmitting end (3) is connected to the receiving end (5) through the remote transmission module (4); the image information acquired by the acquisition end (1) is transmitted to the transmitting end (3) through the wireless transmitting module (2), the transmitting end (3) receives the image information acquired by the acquisition end (1) and transmits the image information to the receiving end (5) through the remote transmitting module (4), and the receiving end (5) receives and stores the image information from the transmitting end (3); the receiving end (5) comprises an acquisition module (51) and an imaging module (52), and the acquisition module (51) acquires image information and transmits the image information to the imaging module (52).

2. The high-definition low-latency 3D stereoscopic wireless remote image transmission system according to claim 1, wherein: the acquisition module (51) comprises a left receiver (511) and a right receiver (512), namely the left receiver (511) receives the image transmitted by the left transmitter (31), and the right receiver (512) receives the image transmitted by the right transmitter (32).

3. The high-definition low-latency 3D stereoscopic wireless remote image transmission system according to claim 1, wherein: the picture is processed at the imaging module (52) and then presented on the viewing mirror (521).

4. The high-definition low-latency 3D stereoscopic wireless remote image transmission system according to claim 1, wherein: the acquisition end (1) comprises a left high-definition camera (11) and a right high-definition camera (12), wherein the left high-definition camera (11) acquires a left real object image, and the right high-definition camera acquires a right high-definition image.

5. The high-definition low-latency 3D stereoscopic wireless remote image transmission system according to claim 1, wherein: the wireless transmitting module (2) and the remote transmission module (4) are respectively internally provided with a 5G communication unit.

6. The high-definition low-latency 3D stereoscopic wireless remote image transmission system according to claim 1, wherein: the acquisition end (1) adopts a high-definition camera to acquire images, the transmitting end (3) adopts a transmitter to transmit the images, and the receiving end (5) adopts 3D glasses to receive and display the images.

7. The high-definition low-latency 3D stereoscopic wireless remote image transmission system according to claim 1, wherein: and the transmitting end (3) and the receiving end (5) are provided with monitoring terminals (33), and the monitoring terminals (33) monitor communication transmission of images.

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