KR100354429B1 - Camera capable of using an infrared film and a control method thereof - Google Patents

Abstract

This invention discloses the camera which can use an infrared film, and its control method. When the user loads the infrared film into the camera for infrared shooting, and then operates the film selecting means, the control means sets the infrared shooting mode. When the initiating means for performing the shooting operation is performed, the measuring means measures the subject distance. The photometric means measures the ambient luminance. The control means adjusts the lens output amount Δf = [(s-2f) -√ (s ² -4fs)] / 2 (f: focal length, S: subject distance) according to the subject distance to be measured and the wavelength difference between infrared rays. The exposure amount is calculated according to the ambient luminance. Next, the lens driving means moves the lens to the corresponding position in accordance with the calculated lens feeding amount, and the shutter driving means opens the shutter according to the calculated exposure amount, whereby photographing is performed. When the film used is not an infrared film, the lens feeding amount is calculated according to a conventional method. Therefore, it is possible to use both an infrared film or a film for visible light mainly used without additional manipulation.

Description

CAMERA CAPABLE OF USING AN INFRARED FILM AND A CONTROL METHOD THEREOF}

The present invention relates to a camera capable of using an infrared film and a control method thereof, and more particularly, to a camera capable of using a general photographic film and an infrared film and a control method thereof.

Hereinafter, a conventional camera will be described with reference to FIG. 1.

1 is a view showing an image formation state of infrared light and visible light in a general convex lens.

In general, in a camera that optically photographs a subject and records it on a film, light corresponding to the subject is imaged on a film positioned at an imaging position through an imaging lens, and since the refractive index is different depending on the wavelength of the light, different wavelengths are used. The positions where a plurality of rays having an image are formed are different.

In general, the longer the wavelength of the light beam, the smaller the refractive index but the longer the focal length. Since infrared light has a longer wavelength than visible light, the focal length of infrared light is longer than visible light as shown in FIG. 1. Therefore, the distance reference for focusing during visible light imaging and the distance reference for infrared photography should be different from each other.

Conventional cameras generally perform visible light imaging and perform a focus adjustment operation according to a subject distance measured based on the visible light. In the case of infrared cameras using infrared film in a manual camera that takes visible light, the user can manually change the distance reference for focusing.

However, in the conventional automatic camera, since the distance reference cannot be changed according to the film used, in case of infrared photography, the focus distance of the infrared light is longer than the visible light so that the focus may not be achieved.

Therefore, when a user wants to take an infrared ray, it is cumbersome to separately use an infrared camera that performs focus adjustment operation based on infrared ray.

Therefore, it is an object of the present invention to provide a camera capable of both photographing using a film for visible light and photographing using an infrared film.

It is also an object of the present invention to provide a method for controlling a camera capable of both visible light imaging and infrared imaging.

1 is a view showing an image formation state of infrared light and visible light in a general convex lens.

2 is a block diagram of a camera capable of using an infrared film according to an embodiment of the present invention.

3 is an operation flowchart of a camera capable of using an infrared film according to an embodiment of the present invention.

4 is a graph showing the amount of lens exposure during infrared imaging and visible light imaging according to an embodiment of the present invention.

In order to achieve this technical problem, the camera capable of using the infrared film according to the present invention calculates the lens exposure amount for focusing in consideration of the difference in the focal length of the infrared ray and visible light when the film used is an infrared film.

A camera capable of using an infrared film according to a feature of the present invention comprises: selecting means for selecting an infrared film use; Initiation means for initiating a photographing operation; Ranging means for measuring a subject distance; Photometric means for measuring ambient luminance; Means for determining whether the film to be used is an infrared film according to the operation of the selection means; according to the subject distance if the lens exposure amount is calculated according to the object distance when the film used is an infrared film and not the infrared film Means for setting the calculated lens exposure amount differently, means for calculating an exposure amount according to the brightness, and means for outputting a lens driving signal according to the lens exposure amount and an exposure signal according to the exposure amount when the starting means is activated. Control means; Lens shifting means for moving the lens in accordance with the lens driving signal; And shutter driving means for opening the shutter according to the exposure signal.

According to another aspect of the present invention, a method of controlling a camera that can use an infrared film includes: determining whether the film used is an infrared film; Measuring a subject distance and brightness; Setting the lens extraction amount calculated according to the distance of the subject when the film used is an infrared film and the lens extraction amount calculated according to the distance of the subject when the film is not an infrared film; Setting an exposure amount according to the brightness; Moving the lens to a corresponding position according to the set lens feeding amount; And shooting by opening the shutter according to the exposure amount.

In the present invention, when the infrared film is used, the lens output amount is determined according to the lens output amount Δf = [(s-2f) -√ (s ² -4fs)] / 2 (f: focal length, S: subject distance). Calculate

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of a camera capable of using an infrared film according to an embodiment of the present invention, and FIG. 3 is a flowchart illustrating an operation of a camera capable of using an infrared film according to an embodiment of the present invention.

As shown in FIG. 1, a camera capable of using an infrared film according to an embodiment of the present invention includes a film selector 10, a light metering unit 20, a ranger 30, and a release switch SW1. ), A control unit 40 connected to these output terminals, a lens driving unit 50 connected to an output terminal of the control unit 40, a shutter unit 60, and a display unit 70.

The film selection unit 10 indicates that the mounted film is an infrared film, and in the embodiment of the present invention, it is composed of a switch.

The light metering unit 20 measures ambient luminance and generally uses a cds device or the like. The ranger 30 measures the distance between the subject and the camera. In the exemplary embodiment of the present invention, the subject distance is measured according to an active method, but is not limited thereto.

The release switch SW1 comprises a switch in which the operation state is sequentially changed to the first release stage and the second release stage by pressing the shutter button (not shown).

The control unit 40 is mounted according to the operation of the film selection unit 10, the film determination unit 41 for determining whether the film is an infrared film or a commonly used film (film for visible light), the measured object distance and the used The photographing operation is performed according to the lens extraction amount calculation unit 43 for calculating the lens extraction amount according to the film, the exposure amount calculation unit 45 for calculating the exposure amount according to the measured ambient luminance, and the calculated lens extraction amount and the exposure amount. The control signal output unit 47 outputs a plurality of control signals (lens drive signal, exposure signal, and the like).

The lens driver 50 rotates the lens motor M according to a control signal from the controller 40 to move the lens for adjusting the focus of the camera to a corresponding position.

The shutter unit 60 controls the exposure time and the exposure amount of the shutter according to a control signal from the controller 40 to perform shooting.

The display unit 70 includes, but is not limited to, a liquid crystal display that displays whether the mounted film is an infrared film or a normal film.

In the embodiment of the present invention, the operations of the light metering unit 20, the ranger 30, the lens driver 50, and the shutter unit 60 are the same as those used in a conventional camera, and thus detailed description thereof will be omitted.

The operation of the camera that can be used in the infrared film according to the embodiment of the present invention having such a structure will be described with reference to FIG. 3.

The controller 40 determines whether the loaded film is an infrared film in a state in which power is applied to the camera and photographing (S110). When the user loads the infrared film to the camera to perform infrared photography and then operates the film selector 10, the film selector 10 outputs a signal according to the infrared film selection to the controller 40.

The film determiner 41 of the controller 40 determines that the currently loaded film is an infrared film according to the signal output from the film selector 10, and sets the photographing mode to the infrared photographing mode (S120).

In this state, when the infrared photographing mode is set, when the user presses the shutter button to shoot, the release switch SW1 is operated to the first release stage. When the first stage of release is operated, the light metering unit 20 measures the ambient luminance, and the metering unit 30 measures the object distance (S130 to S150).

The exposure amount calculator 45 of the controller 40 calculates the exposure amount, that is, the exposure time and the opening amount of the shutter, according to the measured subject brightness, and the lens output amount calculator 43 adjusts the focus adjustment according to the measured subject distance. The amount of extraction of the lens is calculated (S160).

More specifically, since the infrared light has a longer wavelength than the visible light, the focal length of the infrared light is longer than the visible light as shown in FIG. 1. Therefore, when calculating the lens feeding amount by the conventional method corresponding to using the film for visible rays, it will become out of focus. In order to solve this problem, in the embodiment of the present invention, the amount of lens exposure in the use of the film for visible light, that is, in the normal photographing mode and in the infrared film, that is, in the infrared photographing mode is calculated differently.

In general, the wavelength is changed according to the refractive index of the material as shown in Equation 1 below.

λ represents the wavelength of light, n represents the refractive index of the material, and A _{0 to} A ₅ represent the dispersion constant of the material.

As shown in Equation 1, the phenomenon in which the refractive index of the material changes with the wavelength is called dispersion. Since the infrared side has a longer wavelength than the visible light, the refractive index decreases toward the infrared side.

And when the refractive index of the material, that is, the lens becomes smaller, the focal length becomes longer according to Equation 2 below.

f is the focal length, n is the refractive index, r ₁ and r ₂ are the radius of curvature of the lens surface, and t is the lens thickness.

As described above in Equation 1 and Equation 2, the refractive index of the material is changed according to the wavelength of light and the focal length is changed according to the refractive index of the material, so that the embodiment of the present invention is based on the graph shown in FIG. The amount of lens exposure is calculated as follows according to the wavelength difference between visible light and infrared light.

Δf = [(s-2f) -√ (s2-4fs)] / 2

The above f represents the focal length, Δf represents the lens feeding amount, and S represents the object distance (distance from the object point to the film surface).

Next, when the release switch SW1 is operated in the second release stage, the control signal output unit 47 outputs a lens driving signal for moving the lens to the corresponding position according to the lens feeding amount calculated above, and the lens driving unit ( 50) drives the lens motor M according to the lens driving signal so that the focusing lens (not shown) is moved to the set AF (autofocus) position (S170 to S180).

After the focus adjustment operation is performed, the control signal output unit 47 outputs an exposure signal according to the calculated exposure amount so that the photographing is performed. That is, according to the exposure signal, the shutter unit 60 opens the shutter (not shown) for the set exposure time in the set exposure amount, so that infrared light is incident through the photographing lens (not shown) and exposed to the film (S190).

If the loaded film is not an infrared film, the film determination unit 41 of the controller 40 sets the photographing mode to the normal photographing mode and performs a normal photographing operation (S200). That is, when the first stage of the release switch SW1 is activated, the lens output amount is calculated according to a conventional method according to the measured subject distance, and when the second stage of the release switch is operated, the focusing lens is positioned at the set AF position and the shutter is released. Perform the shooting by exposing it.

Since the method of calculating the lens feeding amount according to the distance from the subject during normal shooting of the automatic camera is already known, the detailed description thereof will be omitted.

As described above, according to an embodiment of the present invention, both an infrared film and a general film may be used in an automatic camera.

In addition, there is no need for a separate operation for the use of the infrared film is convenient to use.

In addition, infrared cameras can be used in automatic cameras to take pictures with precise focus.

This invention is capable of various modifications and implementations without departing from the scope of the following claims.

Claims (4)

Selection means for selecting the use of an infrared film; Initiation means for initiating a photographing operation; Ranging means for measuring a subject distance; Photometric means for measuring ambient luminance; Means for determining whether the film to be used is an infrared film according to the operation of the selection means; according to the subject distance if the lens exposure amount is calculated according to the object distance when the film used is an infrared film and not the infrared film Means for setting the calculated lens exposure amount differently, means for calculating an exposure amount according to the brightness, and means for outputting a lens driving signal according to the lens exposure amount and an exposure signal according to the exposure amount when the starting means is activated. Control means; Lens shifting means for moving the lens in accordance with the lens driving signal; And Shutter driving means for opening the shutter according to the exposure signal Including, The control means is a camera capable of infrared film shooting that calculates the lens feeding amount when the film used is an infrared film as follows. Δf = [(s-2f) -√ (s ² -4fs)] / 2 f: focal length △ f: Lens exposure amount S: Subject distance delete Determining whether the film used is an infrared film; Measuring a subject distance and brightness; Setting the lens extraction amount calculated according to the distance of the subject when the film used is an infrared film and the lens extraction amount calculated according to the distance of the subject when the film is not an infrared film; Setting an exposure amount according to the brightness; Moving the lens to a corresponding position according to the set lens feeding amount; And Photographing by opening the shutter according to the exposure amount Including, In the step of calculating the lens feeding amount, when using an infrared film control method of the camera that can use the infrared film to calculate the lens feeding amount as follows. Δf = [(s-2f) -√ (s ² -4fs)] / 2 f: focal length △ f: Lens exposure amount S: Subject distance delete