WO2023029848A1 - Dual input 3d near-eye imaging system - Google Patents

Abstract

Disclosed in the present invention is a dual input 3D near-eye imaging system, comprising: AR glasses (100), a left-eye image acquisition device, and a right-eye image acquisition device. The left-eye image acquisition device acquires a left-eye image signal, the right-eye image acquisition device acquires a right-eye image signal, and an image played by a left-eye microdisplay (2a) is projected to the left eye of a human by means of a left-eye optical imaging lens; an image played by a right-eye microdisplay (2b) is projected to the right eye of the human by means of a right-eye optical imaging lens, and the left-eye image signal is processed by a left-eye image processing chip and inputted into the left-eye microdisplay (2a) for playback; and the right-eye image signal is processed by a right-eye image processing chip and inputted into the right-eye microdisplay (2b) for playback, so that a fused 3D stereoscopic image is formed in the brain of the human. A 3D image is synthesized by simulating the left and right eyes of the human viewing an external object at the same time, so that the image is realistic and natural, and has lossless image quality and high resolution.

Description

Dual-input 3D near-eye imaging system Technical field:

The utility model relates to a dual-channel input 3D near-eye imaging system, which is a system capable of playing digital video images and can be used in medical fields, teaching and the like.

Background technique:

The main core component of the 3D near-eye imaging system is AR glasses, which can superimpose virtual content with the real world, achieving a sensory experience beyond reality. The biggest advantage of AR glasses is that it does not deprive users of their mobility and can freely interact with the real world. It is a mobile computing platform connected to the real world.

There is a problem with the current AR glasses. The AR glasses only have one image signal input port and an image processing chip. Display and right-eye micro-display, the disadvantage of this method is: the existing VR/AR glasses (single-channel) in the market, when processing 3D image signals, one 3D image signal is cut into two-channel signals and then respectively Send it to the left and right eyes of people, which will greatly reduce the definition of the image quality. For example, the original 1920*1080 resolution will be cut into two 960*1080 image quality, which reduces the definition of the 3D image. The 3D stereoscopic image of this kind of AR glasses is different from the image actually seen by the human eye because it imitates the human left eye and right eye to watch the foreign object at the same time.

Invention content:

The purpose of the utility model is to provide a dual-input 3D near-eye imaging system, which solves the problem that the external image signal input of the AR glasses of the 3D near-eye imaging system in the prior art is processed by an image processing chip and sent to the left-eye microdisplay and the right-eye microdisplay together. For display, when processing 3D image signals, one 3D image signal is cut into two signals and then sent to the left eye and right eye of the person respectively, resulting in a significant reduction in the quality of the image, and the 3D stereoscopic image is not as real as the human eye. There are some technical problems with the images received.

The utility model can be realized by following scheme:

The dual-input 3D near-eye imaging system is characterized in that: it includes AR glasses, a left-eye image acquisition device and a right-eye image acquisition device, the left-eye image acquisition device collects left-eye image signals, and the right-eye image acquisition device collects right-eye image signals, The AR glasses include a spectacle frame housing, a left-eye microdisplay, a right-eye microdisplay, a left-eye image processing chip, a right-eye image processing chip, a left-eye optical imaging lens, and a right-eye optical imaging lens. The images played by the left-eye microdisplay pass through The left-eye optical imaging lens is projected to the left eye of the human body; the image played by the right-eye micro-display is projected to the right eye of the human body through the right-eye optical imaging lens, and the left-eye image signal is processed by the left-eye image processing chip and input to the left-eye micro-display for playback; The eye image signal is processed by the right eye image processing chip and input to the right eye microdisplay for playback, forming a fused 3D stereoscopic image in the human brain.

The above-mentioned left-eye image acquisition device is a digital camera or a digital camera; the right-eye image acquisition device is a digital camera or a digital camera.

The spectacle frame housing is also connected to the spectacle legs or the head-mounted device.

The above-mentioned spectacle leg or spectacle frame housing is provided with an image signal input port, and the left-eye image signal and the right-eye image signal are respectively input to the left-eye image processing chip and the right-eye image processing chip through the image signal input port.

The above-mentioned image signal input ports are respectively connected to the left-eye image acquisition device and the right-eye image acquisition device through two HDMI cables.

Both the left-eye image processing chip and the right-eye image processing chip are installed in the spectacle frame housing.

Compared with the prior art, the utility model has the following advantages:

(1) The utility model has the advantages that left-eye image acquisition equipment, left-eye image processing chips, and left-eye microdisplays form a left-eye imaging system; right-eye image acquisition equipment, right-eye image processing chips, and right-eye microdisplays form right-eye imaging systems; Eye imaging system, thus forming two sets of independent non-interfering imaging playback systems. The left-eye image signal is processed by the left-eye image processing chip and input to the left-eye micro-display for playback; the right-eye image signal is processed by the right-eye image processing chip and input to the right-eye micro-display for playback, forming a fused 3D stereoscopic image in the human brain. It is very good to imitate the human left eye and right eye to watch foreign objects at the same time to synthesize 3D images, which is more realistic and natural, with lossless image quality and higher resolution.

(2) Other advantages of the present utility model will be described in detail in the embodiment part.

Description of drawings:

FIG. 1 is a schematic block diagram of AR glasses in the prior art;

Fig. 2 is a block diagram of the utility model;

Fig. 3 is a perspective view of the AR glasses of the present invention;

Fig. 4 is a partial exploded view of the AR glasses of the present invention;

Fig. 5 is an optical path diagram of the imaging of the AR glasses of the present invention;

Fig. 6 is a perspective view of the AR glasses of the present invention after replacing the head-mounted device with the temples.

Detailed ways:

Below in conjunction with accompanying drawing and specific embodiment, the utility model is described in further detail.

Embodiment one:

As shown in Figures 2 to 6, the dual-input 3D near-eye imaging system provided by the utility model is characterized in that it includes AR glasses 100, a left-eye image acquisition device and a right-eye image acquisition device, and the left-eye image acquisition device acquires left Eye image signal, the right eye image acquisition device collects the right eye image signal, the AR glasses include a glasses frame housing 1, a left eye microdisplay 2a, a right eye microdisplay 2b, a left eye image processing chip, a right eye image processing chip, a left eye light Medical imaging lens 3a and right-eye optical imaging lens 3b, the image played by the left-eye microdisplay 2a is projected to the left eye of the human body through the left-eye optical imaging lens 3a; the image played by the right-eye microdisplay 2b is projected to the human body through the right-eye optical imaging lens 3b For the right eye of the human body, the left-eye image signal is processed by the left-eye image processing chip and input to the left-eye micro-display 2a for playback; the right-eye image signal is processed by the right-eye image processing chip and input to the right-eye micro-display 2b for playback, forming a Fused 3D stereoscopic images.

The principle of the utility model is: the left-eye image acquisition device, the left-eye image processing chip, and the left-eye micro-display form a left-eye imaging system; the right-eye image acquisition device, the right-eye image processing chip, and the right-eye micro-display form a right-eye imaging system , thus forming two sets of independent non-interfering imaging playback systems. The left-eye image signal is processed by the left-eye image processing chip and input to the left-eye micro-display for playback; the right-eye image signal is processed by the right-eye image processing chip and input to the right-eye micro-display for playback, forming a fused 3D stereoscopic image in the human brain. It is very good to imitate the human left eye and right eye to watch foreign objects at the same time to synthesize 3D images, which is more realistic and natural, with lossless image quality and higher resolution.

Both the left-eye image processing chip and the right-eye image processing chip are installed in the spectacle frame housing 1, which are not shown in the figure.

The spectacle legs 6 are also connected to the back of the spectacle frame housing 1. The spectacle legs 6 or the spectacle frame housing 1 are provided with an image signal input port 5, and the left eye image signal and the right eye image signal are respectively input to the left eye through the image signal input port 5. Image processing chip and right eye image processing chip. Simple structure and convenient connection.

The left-eye image signal is collected by a left-eye image acquisition device; the right-eye image signal is collected by a right-eye image acquisition device. The above-mentioned left-eye image acquisition device is provided by a digital camera or a digital camera; the right-eye image acquisition device is provided by a digital camera or a digital camera.

The above-mentioned image signal input ports 5 provided behind the spectacle legs 6 or the spectacle frame housing 1 are respectively connected to the right-eye image capture device and the right-eye image capture device through two HDMI cables 7 . Simple structure and convenient connection.

The above-mentioned spectacle frame housing 1 is connected to a head-mounted device 4 for wearing.

The above-mentioned image signal input ports 5 are arranged symmetrically on one side of the spectacle frame housing 1 respectively, and the structure is reasonable and the connection is convenient.

In Fig. 5, only the imaging optical path diagram of the left eye is drawn. In fact, the principle of the imaging optical path diagram of the right eye is basically the same as that of the left eye, so it will not be drawn here.

The above embodiment is a preferred embodiment of the present utility model, but the embodiment of the present utility model is not limited thereto, and any other changes, modifications, substitutions, combinations, and simplifications that do not deviate from the spirit and principles of the present utility model are all All equivalent replacement methods are included in the protection scope of the present utility model.

Claims (6)

1. The dual-input 3D near-eye imaging system is characterized in that: it includes AR glasses, a left-eye image acquisition device and a right-eye image acquisition device, the left-eye image acquisition device collects left-eye image signals, and the right-eye image acquisition device collects right-eye image signals, The AR glasses include a spectacle frame housing, a left-eye microdisplay, a right-eye microdisplay, a left-eye image processing chip, a right-eye image processing chip, a left-eye optical imaging lens, and a right-eye optical imaging lens. The images played by the left-eye microdisplay pass through The left-eye optical imaging lens is projected to the left eye of the human body; the image played by the right-eye micro-display is projected to the right eye of the human body through the right-eye optical imaging lens, and the left-eye image signal is processed by the left-eye image processing chip and input to the left-eye micro-display for playback; The eye image signal is processed by the right eye image processing chip and input to the right eye microdisplay for playback, forming a fused 3D stereoscopic image in the human brain.
2. The dual-input 3D near-eye imaging system according to claim 1, characterized in that: the left-eye image acquisition device is a digital camera or a digital camera; the right-eye image acquisition device is a digital camera or a digital camera.
3. The dual-input 3D near-eye imaging system according to claim 1 or 2, characterized in that: the spectacle frame shell is also connected with spectacle legs or a head-mounted device.
4. The dual-input 3D near-eye imaging system according to claim 3, characterized in that: the spectacle leg or the spectacle frame housing is provided with an image signal input port, and the left eye image signal and the right eye image signal are respectively input to the left eye through the image signal input port. An eye image processing chip and a right eye image processing chip.
5. The dual-input 3D near-eye imaging system according to claim 4, wherein the image signal input ports are respectively connected to the left-eye image acquisition device and the right-eye image acquisition device through two HDMI cables.
6. The dual-input 3D near-eye imaging system according to claim 5, characterized in that both the left-eye image processing chip and the right-eye image processing chip are installed in the spectacle frame housing.

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