JPS61169816A - Device for double-image superimposing and displaying - Google Patents

Abstract

PURPOSE:To easily obtain a superimposed image by forming and displaying an object image as the 1st image by a normal optical method, detecting only distribution information on invisible observation elements which can not be image-formed by a detecting device, and visualizing and displaying it as the 2nd image by the 2nd image display device and superimposing this 2nd image upon the 1st image. CONSTITUTION:An image forming device 2 and a sound collector 3 are installed facing a sound source body 1 and the 1st and the 2nd images are put in focus. The focusing of the 1st image by the image forming device 2 is carried out by operating a lens barrel 12 and the focusing of the 2nd image, on the other hand, is attained by installing a microphone array 4 constituting the detecting device at the sound image formation position of reflected sound from the sound collector 3. Namely, the microphone array 4 is moved to and away from the reflecting surface of the sound collector 3 and positioned 4 where the quantity of light from a light emitting diode array 21 is maximum. Then, the 1st and the 2nd images are focused associatively and then one image is focused automatically by focusing only the other image.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention provides an object image in an observation target and distribution information of non-visible observation elements of the observation target, such as sound pressure distribution, vibration/displacement distribution, Temperature distribution, radiation distribution, internal defects/
This invention relates to a two-image superposition display device that superimposes and displays a second image that visually displays stress distribution and the like.

[Prior art] In order to obtain distribution information of non-visible observation elements in an object to be observed, for example, distribution information such as temperature and vibration generated from the object to be observed is visualized, and the object image is visually observed or converted into an electrical signal. A method can be considered in which the distribution information of the non-visible observation elements is compared in parallel using a monitor display, etc., but such a method not only does not correspond in detail between the two, but also involves the trouble of comparing the two pieces of information in parallel. Two information processing devices are required, which causes problems such as increased device size.

[Problem to be solved by the invention 1 The present invention has been made in view of the above-mentioned points, and has a very simple configuration, and moreover, it is easy to obtain an object image of an object to be observed and non-visible observation elements of this object. It is an object of the present invention to provide a two-image superimposition display device that can superimpose second images formed by visually displaying distribution information of two images.

[Means for Solving the Problems] In order to achieve the above-mentioned object, the two-image superimposed display device according to the present invention converts an object image of an object to be observed into a second image in an imaging section through an optical system. Visualize the distribution information as a second image based on a signal from an imaging device that forms an image as an image, and a detection device that detects distribution information of observation elements that cannot be visually recognized in the observation target and outputs this as an electrical signal. Consisting of a second image display device that displays a second image, and a second image forming lens that displays a second image from the second image display device at the same magnification as the second image and superimposed on the image forming section. It is characterized by what it has done.

[Operation] By arranging the imaging device to face the object to be observed and focusing it, the object image as the first image can be focused on the imaging section using a normal optical method. image. On the other hand, information regarding the sound pressure distribution, temperature distribution, etc. of the object to be observed that needs to be observed while superimposed on the above-mentioned first image, that is, the distribution of non-visible observation elements that cannot be recognized by normal vision. The information is detected by the detection device, converted into an electrical signal, and input to the second image display device. Then, in the second image display device, the above-mentioned information is visually displayed as a second image based on this input signal, and this second image is displayed at a magnification equal to that of the second image through a second image forming lens.
The first and second images are superimposed and displayed in the imaging section.

In this way, only the observation elements that cannot be visualized under normal conditions are visualized as a second image, and the second image thus visualized is formed using a normal optical method to form an object as a second image. Since the image is displayed directly superimposed on the image, the superimposed image of the first and second images can be easily observed with an extremely simple device configuration.

[Example] Hereinafter, an example of the present invention will be described in detail based on the drawings.

In the illustrated embodiment, the object image of the sound source object that is the source of noise is used as the object to be observed, and the sound pressure distribution in the object is formed as a non-visible observation element of the object. A device configuration is shown in which a sound image is visually displayed as a second image, and the first and second images are superimposed and displayed.

That is, as shown in FIG. 1, the object image as the second image of the sound source object l as the object to be observed is formed and displayed on the imaging device 2 using a method similar to that of a normal camera. In order to obtain a sound image as a second image, the sound source object l
A reflective sound collector 3 equipped with a concave curved reflective surface is placed opposite to the sound collector 3, and by making this sound collector 3 act as an acoustic lens, a sound source object 1 is placed in front of the reflective surface.
The sound image of will begin to form. At the position where this sound image is formed, a microphone array 4, which is a processing device in which a large number of micro-indicators are arranged side by side in a matrix, is provided facing the reflective surface of the sound collector 3. Each of the microphones 4 can receive the reflected sound from the sound source object 1 and output a voltage signal corresponding to the respective sound pressure. A second image display device 5 is connected to the rough imaging device 2, and the output signal from the aforementioned microphone array 4 is amplified by an amplifier 6, and based on this amplified signal, the sound pressure distribution of the sound source object 1 is changed into a sound image. It is visualized as a second image.

Then, this second image is guided to the imaging device 2 and the sound source object l
The configuration is such that the image is displayed superimposed on the object image.

Next, FIG. 2 shows a cross section of the aforementioned imaging device 2 and the second image display device 5 connected thereto.

As shown in the figure, the imaging device 2 includes an optical system 1'l formed by combining a plurality of lenses on the front surface of the main body 10, and a lens barrel 12.
The main body 10 is provided with a lens inclined at 45 degrees with respect to the optical axis of the optical system 11 so that focusing can be performed in the optical system 11 by operating the lens barrel 12. A half mirror 13 is attached. The transmission and reflection ratios of the half mirror 13 are selected appropriately depending on the observation conditions. Therefore, the object image of the sound source object 1 is guided into the main body 10 through the optical system 11, but in order to adjust the amount of light incident on the main body 10, a diaphragm 14 is provided in the lens barrel 12. It is being Furthermore, a focus plate 15 is installed on the upper lid of the main body lO, and the object light of the sound source object l is split by a half mirror 13, and the reflected light is displayed as an image on the focus plate 15. When the lid piece 1B that covers the upper part of 15 is opened, this image can be seen from the outside. Further, a darkroom 17 is connected to the rear part of the main body 10, and the darkroom 17 and the inside of the main body 10 are separated by a shutter 18, and a film 18 is mounted inside the darkroom 17. When the shutter 18 is opened, the film 18 is exposed to the object light passing through the half mirror 13.

Next, the second image display device 5 is connected to the main body lO of the image forming device 2.
It consists of a light emitting diode array 21 arranged in a housing 20 connected to the bottom of the microphone array 4 as the detection device described above.
It is equipped with a large number of light emitting diodes arranged in parallel so as to correspond to each of the microphones constituting it, and each of these light emitting diodes is connected to a microphone, respectively, and the light emitting diodes are connected to the respective microphones to generate a sound according to the sound pressure of the sound source object l received by each microphone. The light is turned on depending on the amount of light, and by converting this into an image as the distribution of light in the light emitting diode array 21, it is visually displayed as a second image. A mask plate 22 is attached above the light emitting diode array 21, and the mask plate 22 has a large number of through holes 2 through which light from each light emitting diode of the light emitting diode array 21 passes.
3 is perforated, so that the second image on the light emitting diode array 21 can be clearly displayed. A filter 24 is further removably provided in the housing 20, and the filter 24 diffusely reflects the light image from the light emitting diode array 21, thereby creating a planar light image as a second image. It is now possible to add breadth.

This is used as necessary depending on the type and content of the observation element. Furthermore, this second image is formed by a second image forming lens 25.
It is guided into the main body IO through an aperture 26 from an opening 27 formed at the bottom of the main body IO, and is divided by a half mirror 13, and a part is placed on the focus plate 15.
The image is displayed with the same magnification as the image, and when the shutter 18 is opened, it is possible to photograph the image superimposed on the film 19 with the second image. Note that the same magnification as the second image can be achieved by providing a zoom lens in the first image forming device or by changing the distance between the object and the first image forming device.

As described above, by using the two-image superposition device configured, it is possible to easily and accurately detect and measure in which part of the sound source object l noise is generated.

That is, as shown in FIG. 1, the imaging device 2 and the sound collector 3 are installed facing the sound source object l, and the first and second images are focused. Focusing of the second image can be performed by operating the lens barrel 12 in the same way as in a normal camera, and it can also be done by attaching a zoom lens or the like to the lens barrel 12 if necessary. . On the other hand, the second image is focused by placing the microphone array 4 constituting the detection device at the sound image formation position of the sound reflected by the sound collector 3. That is, this moves the microphone array 4 in the direction of close ionization with respect to the reflective surface of the sound collector 3, and moves the microphone array 4 to the position where the sound pressure received by the microphone array 4 is maximum, in other words, the light amount of the light emitting diode array 21. This is done by positioning the microphone array 4 at a position where the maximum value is obtained. Therefore, by configuring the first and second images to be focused in conjunction with each other, by focusing on one, the other can be automatically focused.

The third image is guided into the main body 10 through the optical system 11, reflected by the half mirror 13, and displayed as an image on the focus plate 15. In addition, the sound pressure distribution of the sound source object l, which is a non-visual observation element that cannot be recognized visually, is detected as a sound image by having the microphone array 4 that constitutes the detection device receive the sound, and this is converted into a voltage signal. The converted output signal is amplified by the amplifier 6 and inputted to the light emitting diode array 21, thereby causing each light emitting diode of the light emitting diode array 21 installed in a state corresponding to each microphone in the microphone array 4 to emit light. let In this way, the sound pressure distribution of the sound source object 1 is visually displayed as an image of light emitted by the light emitting diode array 21. The second image visualized in this manner advances into the main body 10 toward the half mirror 13 via the second image forming lens 25, and
The light that has passed through the sound source object 1 is displayed on the focus plate 15 in a state where it is superimposed on the -th image, and the position of the sound source in the sound source object 1 can be detected and measured. Also, by opening the shutter 18 of the imaging device 2, the first and second images are transferred to the film 1.
8 can be photographed and recorded.

In the above-described embodiment, the sound image of the sound source object l is visualized and displayed as a second image in the imaging device 2.
The main point is to use the object image as the observation target as the first image, detect non-visible observation elements of the observation target that cannot be visually recognized, and It is only necessary to visually display the image as a second image and superimpose it on the above-mentioned first image. By detecting stress distribution, stress distribution, temperature distribution, radiation distribution, internal defect e-stress distribution, etc., these non-visible observation elements can be displayed as a second image superimposed on the second image consisting of the object image. I can do it. The display timing of the second image can be either simultaneous array display or sequential display by scanning. In addition to the camera, a microscope or a telescope may be used as the imaging device for the second image. Further, although the imaging device has substantially the same structure as a normal camera, if there is no need to photograph and record superimposed images, there is no need to provide the darkroom 17, film 18, etc.

[Effects of the Invention] As detailed above, the two-image superposition device according to the present invention has the following effects:
The object image as the first image is formed and displayed using a normal optical method, the detection device detects only the distribution information of non-visible observation elements that cannot be formed into an image, and the second image is displayed using the second image display device. Since the second image is visually displayed as , and the second image is superimposed on the second image, it is possible to easily form a superimposed image with a simple structure.

[Brief explanation of the drawing]

FIG. 1 is a configuration explanatory diagram showing a state in which the two-image superposition device of the present invention is used in a sound source exploration φ measuring device, and FIG. 2 is a sectional view of the two-image superposition device. 1. Sound source object, 2. φ imaging device, 4. Microphone array, 6. Second image display device, 11. Q optical system.
13...half mirror 115...focusing plate, 1
9. Film, 21-. Light emitting diode array, 25@. Lens for second image formation. Figure 1

Claims (4)

[Claims] (1) An imaging device that forms an object image of an object to be observed as a first image on an imaging unit via an optical system, and detects distribution information of non-visible observation elements in this object and converts it into an electrical a second image display device that visualizes and displays the distribution information as a second image based on a signal from a detection device output as a signal; and a second image from the second image display device is set at the same magnification as the first image. A two-image superposition device comprising: a second image-forming lens that is superimposed on the image-forming section for display. (2) The image forming section is composed of an image forming surface for a monitor and a film for recording, and the first image and the second image are divided by a half mirror, and this is divided into the image forming surface and the film. A two-image superimposed display device according to claim 1, characterized in that it is configured to display images. (3) The second image display device is constructed by arranging light emitting diodes or liquid crystals in a matrix pattern that light up in response to information signals from the object to be observed. 2-image overlapping display device. (4) The two-image overlapping display device according to claim 1, wherein the first image forming device includes a zoom lens.