CN211954618U - Miniaturized imaging system for simulating target and background - Google Patents

Abstract

The utility model discloses a miniaturized formation of image system for simulating target and background, include: the device comprises a simulation target generation module, a simulation background generation module, a collimation optical unit and a detector; the simulation target generation module and the simulation background generation module respectively comprise a corresponding light source, a brightness adjustment module, a corresponding target and a beam combining prism; the natural light emitted by the two light sources respectively passes through the brightness adjusting module and the corresponding target in sequence to form a target light beam and a background light beam, the target light beam and the background light beam are combined into a mixed light beam through the beam combining prism and enter the collimating optical unit, and the collimating optical unit performs optical treatment on the mixed light beam and then projects the mixed light beam on the detector to form an infinite target source. The utility model adopts double fly-eye lenses as the light homogenizing component; the device is small in size and light in weight, the test result cannot be influenced by changing the imaging test place, and the accuracy rate of the test result is high.

Description

Miniaturized imaging system for simulating target and background

Technical Field

The utility model relates to a photoelectric detection equips technical field, concretely relates to miniaturized imaging system for simulating target and background.

Background

The main imaging system in the photoelectric detection equipment is a television imaging system, and one of important performance indexes is the target capturing capacity, so how to improve the target capturing capacity of the television imaging system becomes a key link in the development process of the photoelectric imaging system.

In a laboratory research stage, a set of imaging system is often needed to simulate target patterns of a target and a background so as to test the target capturing capability of the imaging system, while an integrating sphere scheme is mostly adopted in the process of capturing the target of the existing imaging system, and the integrating sphere scheme needs to be reinstalled, debugged and the like in different test environments, so that test result deviations in different places may be generated. In addition, the volume of the integrating sphere is large, so that the whole system is large in volume and is not beneficial to final production.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems in the prior art, the utility model aims to provide a miniaturized imaging system for simulating a target and a background, which adopts a double fly-eye lens as a light-homogenizing component and generates target test patterns with different contrasts by changing the brightness of the target and the background; the device is small in size and light in weight, the test result cannot be influenced by changing the imaging test place, and the accuracy rate of the test result is high.

In order to achieve the above purpose, the present invention adopts the following technical solution.

A miniaturized imaging system for simulating an object and a background, comprising: the device comprises a simulation target generation module, a simulation background generation module, a collimation optical unit and a detector; the simulation target generation module and the simulation background generation module respectively comprise a corresponding light source, a brightness adjustment module, a corresponding target and a beam combining prism; natural light emitted by the two light sources respectively passes through the brightness adjusting module and the corresponding target in sequence to form a target light beam and a background light beam, the target light beam and the background light beam are combined into a mixed light beam through the beam combining prism and enter the collimating optical unit, and the collimating optical unit performs optical treatment on the mixed light beam and then projects the mixed light beam on the detector to form an infinite target source;

the brightness adjusting module comprises two attenuation pieces, two fly-eye lenses and a brightness measuring and controlling unit; two signal input ends of the brightness measurement and control unit are respectively and electrically connected with signal output ends of the two fly-eye lenses, and two signal output ends of the brightness measurement and control unit are respectively and electrically connected with control ends of the two attenuation sheets;

each light source corresponds to one attenuation sheet, one fly-eye lens and one target, and a group of attenuation sheets, fly-eye lenses, targets and beam combining prisms corresponding to one light source are sequentially arranged and fixed in one shell along the optical axis of natural light emitted by the light source.

The utility model discloses technical scheme's characteristics lie in with further improvement:

further, for a light source, the ratio of the distance between the fly-eye lens and the target to the distance between the fly-eye lens and the midpoint of the line connecting the attenuation sheet and the target is 8/3.

Furthermore, the brightness measurement and control unit comprises two brightness meters and a controller, each brightness meter corresponds to one fly-eye lens and is used for collecting the brightness value in the fly-eye lens and transmitting the brightness value to the controller, and the controller adjusts the luminous flux of the corresponding attenuation sheet according to the received brightness value.

Further, the light source is a broad spectrum light source.

Further, the collimating optical unit includes a primary mirror and a secondary mirror for converting an input mixed beam into a parallel beam output.

Further, the two targets are arranged in conjugate relation to the beam combining prism.

Still further, the target is a four-bar target.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model adopts the double fly-eye lens as the dodging component, and generates target test patterns with different contrasts by changing the brightness of the target and the background; the device has small volume and light weight, and the change of the imaging test site does not influence the test result, so the accuracy of the test result is high; it is mainly used for simulating target patterns of targets and backgrounds in laboratories. Adopt the utility model discloses the system can reduce whole TV imaging system's volume greatly to carry out the lightweight design.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic diagram of a miniaturized imaging system for simulating a target and a background according to an embodiment of the present invention;

in the above figures, 1 light source; 2, a brightness adjusting module; 21 an attenuation sheet; 22 fly-eye lenses; 23, a brightness measurement and control unit; 3, targeting; 4, a beam combining prism; 5 a collimating optical unit; 51 a primary mirror; a mirror for 52 times; 6, a detector.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to examples, but those skilled in the art will understand that the following examples are only for illustrating the present invention and should not be construed as limiting the scope of the present invention.

Referring to fig. 1, the present invention provides a miniaturized imaging system for simulating an object and a background, comprising: the device comprises a simulation target generation module, a simulation background generation module, a collimation optical unit 5 and a detector 6; the simulation target generation module and the simulation background generation module respectively comprise a corresponding light source 1, a brightness adjustment module 2, a corresponding target 3 and a beam combining prism 4; natural light emitted by the two light sources 1 respectively passes through the brightness adjusting module 2 and the corresponding target 3 in sequence to form a target light beam and a background light beam, the target light beam and the background light beam are combined into a mixed light beam through the beam combining prism 4 and enter the collimating optical unit 5, and the collimating optical unit 5 optically processes the mixed light beam and then projects the mixed light beam on the detector 6 to form an infinite target source;

the brightness adjusting module 2 comprises two attenuation sheets 21, two fly-eye lenses 22 and a brightness measuring and controlling unit 23; two signal input ends of the brightness measurement and control unit 23 are respectively and electrically connected with signal output ends of the two fly-eye lenses 22, and two signal output ends of the brightness measurement and control unit 23 are respectively and electrically connected with control ends of the two attenuation pieces 21; each light source 1 corresponds to one attenuation sheet 21, one fly-eye lens 22 and one target 3, and a group of attenuation sheets 21, fly-eye lenses 22, targets 3 and beam combining prisms 4 corresponding to one light source 1 are sequentially arranged and fixed in one shell along the optical axis of natural light emitted by the light source 1.

In the above embodiments, the simulated target generation module is configured to generate a target 3 light beam, the simulated background generation module is configured to generate a background target 3 light beam, the collimating optical unit 5 is configured to perform optical design on the input mixed light beam to form an infinite target source, and the detector 6 is configured to image the target source and test the imaging quality. The simulated target generation module and the simulated background generation module are respectively composed of a light source 1, a brightness adjustment module 2, a target 3 and a beam combining prism 4, natural light emitted by the two light sources 1, namely halogen lamps, respectively and sequentially passes through the brightness adjustment module 2, the target 3 or the background target 3 to form a target light beam and a background light beam, the target light beam and the background light beam are combined into a mixed light beam through the beam combining prism 4 and enter a collimation optical unit 5, and the collimation optical unit 5 performs optical treatment on the mixed light beam and then projects the mixed light beam on a detector 6 to form an infinite target source.

The brightness adjusting module 2 consists of two attenuation sheets 21, two fly-eye lenses 22 and a brightness measuring and controlling unit 23; the fly-eye lens 22 mainly plays a role in light uniformization, the brightness control of the fly-eye lens 22 adopts closed-loop control, the real-time monitoring of the brightness in the fly-eye lens 22 is realized through a brightness meter in the brightness measurement and control unit 23, and the brightness value is transmitted to a controller in the brightness measurement and control unit 23 to be used as feedback information of the closed-loop control; meanwhile, the feedback information is compared with the set brightness value to generate a control command to control the attenuation sheet 21 to change the luminous flux of the attenuation sheet, so that the brightness change of the simulation target generation module or the simulation background generation module is realized. Each light source 1 corresponds to one attenuation sheet 21, one fly-eye lens 22 and one target 3, and a group of attenuation sheets 21, fly-eye lenses 22, targets 3 and beam combining prisms 4 corresponding to one light source 1 are sequentially arranged in one shell along the optical axis of natural light emitted by the light source 1. The light source 1, the attenuation sheet 21, the fly eye lens 22, the target 3, the beam combining prism 4 and other components in the utility model are arranged in a shell; when the test is carried out in different places, only the whole shell needs to be moved, installation and debugging are not needed, the test device is very convenient, the measurement deviation of different places is avoided, and the measurement accuracy is improved.

Referring to fig. 1, according to an embodiment of the present invention, for a light source 1, the ratio of the distance between the fly-eye lens 22 and the target 3 to the distance between the fly-eye lens 22 and the midpoint of the line connecting the attenuation sheet 21 and the target 3 is 8/3.

Exemplarily, the distance between the fly-eye lens 22 and the target 3 is 8mm, and the midpoint of the connecting line between the attenuation sheet 21 and the target 3 is point a, the distance between the fly-eye lens 22 and the point a is 3mm, so that the target 3 and the background target 3 are arranged to be close to the light outlet of the fly-eye lens 22, the fly-eye lens 22 has a good light-homogenizing effect, and the final imaging effect is ensured.

Referring to fig. 1, according to the utility model discloses an embodiment, luminance observing and controlling unit 23 contains two luminance meters and controller, and every luminance meter corresponds fly-eye lens 22 for gather the luminance value in fly-eye lens 22, and pass to the controller with the luminance value, the controller corresponds the luminous flux of decay piece 21 according to the luminance value adjustment of receiving, adjust the luminance of background and target with this, and then adjust the contrast of background and target in the 3 test images of final target, obtain the directly perceived pattern that different luminance produced, can reflect the resolution detail of 3 test patterns of target, improve the test accuracy.

Referring to fig. 1, according to one embodiment of the present invention, the collimating optical unit 5 comprises a primary mirror 51 and a secondary mirror 52 for converting an input mixed beam into a parallel beam output; the target 3 and the background target 3 form an infinite target source after passing through the collimating optical unit 5, thereby providing a simulated target and background test chart for the television imaging system.

Referring to fig. 1, according to one embodiment of the present invention, two targets 3 are arranged in conjugate with respect to a beam combining prism 4.

Referring to fig. 1, according to one embodiment of the present invention, the target 3 is a four-bar target.

In the above embodiment, the background target 3 and the target 3 are four-bar targets respectively, the four-bar targets have intuitive periodic bar patterns, the manufacturing is simple, the resolution details can be intuitively reflected, and the four-bar targets with different contrasts under a certain spatial frequency are resolved and identified by a television imaging system during testing, so that the target background pattern is simulated.

The utility model adopts the structure of double compound eye lenses 22 to form the target source generator, so that the volume and the mass of the whole system are greatly reduced, and the carrying is convenient; even if the device is carried to other test places for testing, the device can be directly used without debugging the light path again, thereby really achieving the purposes of miniaturization and portability. Meanwhile, the measurement error caused by repeated tests is avoided, and the measurement accuracy is improved.

Although the invention has been described in detail in this specification with reference to specific embodiments and illustrative embodiments, it will be apparent to those skilled in the art that certain changes and modifications can be made therein without departing from the scope of the invention. Therefore, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (7)

1. A miniaturized imaging system for simulating a target and a background, comprising: the device comprises a simulation target generation module, a simulation background generation module, a collimation optical unit and a detector; the simulation target generation module and the simulation background generation module respectively comprise a corresponding light source, a brightness adjustment module, a corresponding target and a beam combining prism; natural light emitted by the two light sources respectively passes through the brightness adjusting module and the corresponding target in sequence to form a target light beam and a background light beam, the target light beam and the background light beam are combined into a mixed light beam through the beam combining prism and enter the collimating optical unit, and the collimating optical unit performs optical treatment on the mixed light beam and then projects the mixed light beam on the detector to form an infinite target source;

the brightness adjusting module comprises two attenuation pieces, two fly-eye lenses and a brightness measuring and controlling unit; two signal input ends of the brightness measurement and control unit are respectively and electrically connected with signal output ends of the two fly-eye lenses, and two signal output ends of the brightness measurement and control unit are respectively and electrically connected with control ends of the two attenuation sheets;

each light source corresponds to one attenuation sheet, one fly-eye lens and one target, and a group of attenuation sheets, fly-eye lenses, targets and beam combining prisms corresponding to one light source are sequentially arranged and fixed in one shell along the optical axis of natural light emitted by the light source.

2. The miniaturized imaging system of claim 1 wherein, for a single light source, the ratio of the distance between the fly-eye lens and the target to the distance between the fly-eye lens and the midpoint of the line connecting the attenuation sheet and the target is 8/3.

3. The miniaturized imaging system for simulating the objects and the background according to claim 1, wherein the brightness measurement and control unit comprises two brightness meters and a controller, each brightness meter corresponds to one fly-eye lens and is used for collecting the brightness value in the fly-eye lens and transmitting the brightness value to the controller, and the controller adjusts the luminous flux of the corresponding attenuation sheet according to the received brightness value.

4. A miniaturized imaging system for simulating targets and backgrounds according to claim 1, characterized in that said light source is a broad spectrum light source.

5. A miniaturized imaging system for simulating targets and backgrounds according to claim 1, characterized in that said collimating optical unit comprises a primary mirror and a secondary mirror for converting an input mixed beam into a parallel beam output.

6. The miniaturized imaging system of claim 1 wherein the two targets are arranged in conjugate relation to the beam combining prism.

7. The miniaturized imaging system for simulating an object and a background according to claim 6, wherein the target is a four-bar target.

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