MULTI-OPTICAL ADJUSTABLE SHOOTING SYSTEM

Abstract

The present invention discloses a multi-optical adjustable shooting system, including an optical lens, where a spectroscopical module that can split a light wave transmitted from the optical lens into several light waves in different wavelength ranges is disposed on an imaging side of the optical lens; the shooting system further includes an optical path adjustment mechanism configured to adjust an optical path and a photosensitive chip configured to receive a light signal; the shooting system further includes an image processing system that can integrate and output light waves received by various photosensitive chips; and the optical path adjustment mechanism is disposed between the spectroscopical module and the photosensitive chip. In the present invention, high definition of a shot image is implemented, image color restoration is good, and clear imaging can be implemented even in low illuminancy.

Claims

1. A multi-optical adjustable shooting system, comprising an optical lens (1), wherein a spectroscopical module (2) that can split a light wave transmitted from the optical lens (1) into several light waves in different wavelength ranges is disposed on an imaging side of the optical lens (1); the shooting system further comprises an optical path adjustment mechanism (3) configured to adjust an optical path and a photosensitive chip (4) configured to receive a light signal; the shooting system further comprises an image processing system (5) that can integrate and output light waves received by various photosensitive chips (4); and the optical path adjustment mechanism (3) is disposed between the spectroscopical module (2) and the photosensitive chip (4).

2. The multi-optical adjustable shooting system according to claim 1, wherein the spectroscopical module (2) comprises at least one spectroscopical component.

3. The multi-optical adjustable shooting system according to claim 1, wherein the shooting system comprises at least one spectroscopical module (2).

4. The multi-optical adjustable shooting system according to claim 3, wherein the shooting system comprises at least two photosensitive chips (3).

5. The multi-optical adjustable shooting system according to claim 3, wherein the shooting system comprises two spectroscopical modules (2).

6. The multi-optical adjustable shooting system according to claim 4, wherein the shooting system comprises three photosensitive chips (3).

7. The multi-optical adjustable shooting system according to claim 4, wherein the shooting system comprises one optical path adjustment mechanism (3).

8. The multi-optical adjustable shooting system according to claim 4, wherein the shooting system comprises at least two optical path adjustment mechanisms (3), and a quantity of the optical path adjustment mechanisms (3) is the same as a quantity of the photosensitive chips (4).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] The following further describes a specific implementation of the present invention in detail with reference to the accompanying drawing, where:

[0022] FIG. 1 is a schematic diagram of the present invention.

[0023] Descriptions about the accompanying drawing: 1. Optical lens; 2. Spectroscopical module; 3. Optical path adjustment mechanism; 4. Photosensitive chip; 5. Image processing system.

DETAILED DESCRIPTION

[0024] The following describes an implementation of the present invention in detail with reference to the accompanying drawing.

[0025] As shown in FIG. 1, a multi-optical adjustable shooting system, including an optical lens 1, where a spectroscopical module 2 that can split a light wave transmitted from the optical lens 1 into several light waves in different wavelength ranges is disposed on an imaging side of the optical lens 1; the shooting system further includes an optical path adjustment mechanism 3 configured to adjust an optical path and a photosensitive chip 4 configured to receive a light signal; and the shooting system further includes an image processing system 5 that can integrate and output light waves received by various photosensitive chips 4. The optical path adjustment mechanism 3 is disposed between the spectroscopical module 2 and the photosensitive chip 4. The optical path adjustment mechanism 3 that adjusts an optical path enables light of various wavelength ranges to form a clear image on the back photosensitive chip 4.

[0026] As shown in FIG. 1, in this embodiment, the spectroscopical module 2 includes at least one spectroscopical component, and can split a light wave transmitted from the optical lens 1 into multiple light waves in different wavelength ranges. A quantity of spectroscopical components is not specifically limited herein.

[0027] As shown in FIG. 1, in this embodiment, the shooting system includes at least one spectroscopical module 2. There may be two or more spectroscopical modules, and a quantity of the spectroscopical modules is not specifically limited herein. As shown in FIG. 1, in this embodiment, the shooting system includes at least two photosensitive chips 4. There may be three or more photosensitive chips, and a quantity of the photosensitive chips is not specifically limited herein.

[0028] As shown in FIG. 1, in this embodiment, the shooting system includes one optical path adjustment mechanism 3, that is, the optical path adjustment mechanism is disposed between only one spectroscopical module and one photosensitive chip. Certainly, the shooting system also includes at least two optical path adjustment mechanisms 3, and a quantity of the optical path adjustment mechanisms 3 is the same as the quantity of the photosensitive chips 4.

[0029] In a manner of using the spectroscopical modules 2 and matching multiple photosensitive chips 4 that receive light waves in different wavelength ranges, the spectroscopical modules 2 split light emergent from the optical lens 1 into different light waves in different wavelength ranges, optical paths for the different light are separately adjusted by the optical path adjustment mechanism 3, and then the different light separately forms a clear image on a corresponding photosensitive chip 4. The different photosensitive chips 4 separately receive light waves in particular wavelength ranges, and finally an image processing system 5 implements image restoration and reproduction, thereby improving definition of an optical system, improving color restoration, and implementing clear imaging for the shooting system even in a low illuminancy environment.