JPH0473132B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an overhead projector, and more particularly to an overhead projector capable of detecting any position on a document film.

[Prior Art] A conventional overhead projector is shown in FIG.

A light-transmissive original film 3 is placed on a mirror Fresnel lens 2 placed on a box stand 1, and light is irradiated from a light source 4 above the original film 3. The reflected light is projected onto a screen (not shown) by a reflection mirror 6 via a projection lens 5.

By the way, in this type of overhead projector, for example, when automatically enlarging and projecting a part of the original film 3, the area to be enlarged on the original film 3 is detected, and the area to be enlarged is moved through the zoom lens. It is considered that it will be necessary to automatically position the image forming lens 5 on the optical axis of the imaging lens 5, etc.

At this time, it is first necessary to design a position detection method for detecting a specific part of the original film 3, and examples of this type of position detection method include, for example, Japanese Patent Laid-Open Nos. 57-8532 and 57-8533. By using the technique disclosed in the above publication, a specific portion of an image projected on a screen is specified and the specified position is detected.

[Problems to be Solved by the Invention] However, in the device described in JP-A-57-8532, the position detection means is incorporated around the screen, so the device itself becomes large.
In the device described in Publication No. 8533, since the position detecting means is provided on the bottom surface of the screen, there is little risk of the device itself becoming larger, but the image of the position detecting means may overlap the original image and deteriorate the quality of the original image. To avoid this, a special touch panel made of a thin film of transparent conductor is required, which poses a technical problem in that the device becomes more complex.

The present invention has been developed based on the above-mentioned viewpoints, and while maintaining the original function of maintaining the quality of the projected image of the original film, it is possible to increase the size of the screen.
With simple operation and without complications,
Can accurately detect any position on the original film,
An object of the present invention is to provide an overhead projector that can maintain good quality of a partial projection image for the detection site.

[Means for Solving the Problems] That is, the present invention provides an overhead projector that irradiates light onto an original film and projects an image of the original film onto a screen via an illumination light converging member and a projection lens. Assuming that
a mirror Fresnel lens as an illumination light convergence member on which the original film is placed; a position specifying means having at least a magnetic material at the tip for specifying an arbitrary position of the original film placed on the mirror Fresnel lens; Two sets of conducting wires arranged in parallel below the Fresnel lens and crossing each other in a matrix, a position detecting means for detecting the position of a matrix element in which the mutual induction coefficient of the matrix-like conducting wires changes, and The apparatus is characterized by comprising positioning means for positioning the specified position of the original film on the optical axis of the projection lens based on the information.

[Effect]

According to the above-mentioned technical means, when an arbitrary position on the original film is designated by the position designating means whose tip is made of a magnetic material, the mutual induction coefficient of the matrix-shaped conductive wires located directly below the position designation means becomes large. A position detection means detects the position of the corresponding matrix element based on the change in mutual induction coefficient.

At this time, since the matrix-like conducting wire is provided below the mirror Fresnel lens, the matrix-like conducting wire is not placed in the optical path of the document illumination light, and there is no risk that the image of the matrix-like conducting wire will overlap the original image. .

The alignment means aligns the specified position of the original film on the optical axis of the projection lens based on the information from the position detection means, so that the specified position of the original film is focused on a screen (not shown). Partial projection is accurately performed in the state.

[Examples] Hereinafter, the present invention will be described in detail based on examples shown in the accompanying drawings.

FIG. 2 shows a film mounting table according to an embodiment of an overhead projector with an automatic partial enlargement projection function to which the present invention is applied. A film 3 with the following information written thereon is placed thereon. The image on the film 3 is as shown in FIG.
The irradiated light is projected onto the screen via the mirror Fresnel lens 2, the projection lens 5, and the reflection mirror 6. A fixing plate 7 is fixed to the left end of the box stand 1, and an L-shaped platform 8 that moves in the vertical direction is arranged thereon. A long hole 9 is bored in the longitudinal part of the platform 8, and a stud 10 fixed to a fixing plate 7 is passed through the hole 9 so that the platform 8 can move freely along this hole. A rack is provided at the left end of the platform 8, and this rack holds the motor 1 fixed to the box stand 1 via the pinion 11.
2 gear, and the platform 8 is driven by the motor 12. platform 8
An L-shaped platform 13 that moves laterally is placed on the lateral part of the platform 1.
A long hole 14 is drilled in the lateral part of 3, and a stud 15 fixed to the platform 8 passes through it. A rack is provided at the lower end of the platform 13, and a motor 16 fixed to the platform 8 allows the platform 13 to be moved laterally.
Adhesive is applied to the vertical part of the platform 13, and the lower left edge of the film 3 is fixed with adhesive.
To allow films to be replaced freely. At the bottom of the mirror Fresnel lens 3 in the box stand 1, for the mirror Fresnel lens area shown by the broken line in FIG.
The conducting wire 17 is placed as shown in the figure. This conducting wire is formed by printed wiring.

In this embodiment, as shown in FIG. 3, the conductive wire 17 is switched independently for each of the three contacts Y1, Y2, and Y3 of the switch 18 in the Y direction (corresponding to the vertical direction in FIG. 3). The Y-direction loop-forming conducting wire arranged in parallel and the three contacts X1, X2, and X3 of the changeover switch 19 independently
(corresponding to the left-right direction in the figure), the X-direction loop-forming conducting wires are arranged in parallel and intersecting at right angles.

Then, the Y-direction loop forming conductor wire of the conductor wire 17 is connected to the pulse generator 20 via the changeover switch 18.
On the other hand, the conducting wire 17 for forming an X-direction loop is connected to the amplifier 2 via a changeover switch 19.
Connected to 1.

Further, the changeover switch 18 sequentially switches the contacts Y1, Y2, and Y3, and the changeover switch 19 sequentially switches the contacts X1, X2, and X3, but the switching speeds of the changeover switches 18 and 19 are different. The switching speed of the switch 18 is set to three times the switching speed of the changeover switch 19, and while the changeover switch 19 is in conduction with any of the contacts X1 to X3, the changeover switch 18 is
Y2 and Y3 are switched sequentially.

In such a matrix-shaped conducting wire 17, a pulse current sequentially flows through the Y-direction conducting wire loop including the respective contacts Y1, Y2, and Y3 by the switching operation of the changeover switch 18.
The magnetic flux generated by the pulsed current interlinks with the X-direction conductive wire loop including the contacts X1, X2, and X3, which are sequentially turned on by the switching operation of the changeover switch 19, and an induced voltage is sequentially generated.

However, the conductor wire for forming a loop in the Y direction and the
Since the mutual induction coefficient between the X-direction loop-forming conductor and the X-direction loop-forming conductor is small, the induced voltage generated in the X-direction loop-forming conductor is extremely small, and even after amplification by the amplifier 21,
It does not reach the stage of driving the next stage circuit.

However, if a magnetic material is brought close to a specific matrix element of the matrix-shaped conducting wire 17,
The magnetic flux generated by the pulsed current flowing through the Y-direction conducting wire loop is converged by the magnetic material, and the magnetic flux interlinking with the matrix element increases. For this reason, the mutual induction coefficient of the relevant matrix portion becomes large, and a large induced voltage is generated in the corresponding X-direction loop forming conductor, and the next stage circuit, that is,
It is designed to drive a position designation signal generation circuit 22 shown in FIG.

Further, FIG. 4 shows a drive control system for controlling the position of the film 3 based on information obtained from the matrix-shaped conducting wires 17.

In the figure, the position designation signal generation circuit 22
, when the output level of the amplifier 21 is set to a predetermined threshold (specifically, when a magnetic substance is brought close to a specific matrix element of the matrix-shaped conducting wire 17, the X-direction loop-forming conducting wire containing the corresponding matrix element is A high level signal is output when the induced voltage level exceeds a threshold value for detecting the induced voltage level generated from the voltage.

Further, reference numeral 23 is constituted by, for example, a counter that counts the reference clock, and the changeover switch 1
Which contacts Y1, Y2, Y3, X1, X are 8 and 19?
2, a timing signal indicating whether X3 is selected, specifically X1, Y1, X1, Y2, X1, Y3,
This is an XY switch position signal generation circuit that repeatedly generates position signals corresponding to the coordinates of X2, Y1, . . . X3, Y3 at a predetermined timing cycle.

Further, reference numeral 24 detects that a position specifying operation using a magnetic body has been performed in response to a signal from the position specifying signal generating circuit 22, and detects the timing at which the detection signal from the position specifying signal generating circuit 22 is generated.
This determination circuit detects and outputs the position signal from the XY switch position signal generation circuit 23 to determine which matrix element of the matrix conductor 17 is designated by the magnetic body.

The signal from the determination circuit 24 is input to the control circuit 25, which generates signals in the X and Y directions corresponding to the deviation between the central part of the mirror Fresnel lens 2 located on the optical axis of the projection lens 5 and the designated position. do. These signals are input to the X-direction drive circuit 26 and the Y-direction drive circuit 27, respectively, to drive the motors 16 and 1 in FIG.
Drive 2. The reset switch 28 resets the X and Y direction signals of the control circuit 25 to the zero position, drives the motors 16 and 12, and operates to return the film 3 to its original position.

The operation of this embodiment configured as above will be described below.

Now, if we were to enlarge and project the upper left part of the film 3 in Figure 2, we would specify that part with a position specifying tool, but the position specifying tool has a pen-like shape that is easy to hold, and there is iron or other metal on the tip. A magnetic material is attached. Then, the magnetic body will be located at the coordinate position of X ₁ and Y ₁ in FIG. 3, and the mutual induction coefficient in this area will become large. Therefore, a pulse signal is generated in the _X1 loop of the position signal generating circuit shown in FIG.

Meanwhile, the XY switch position signal generation circuit 23 in FIG. 4 sequentially outputs X ₁ , Y ₁ , X ₁ ,
The signals of Y ₂ , X ₁ , Y ₃ , X ₂ , Y ₁ , ... are sent to the judgment circuit 2
It is output to 4. In the determination circuit 24, X ₁ , Y ₁
It is determined that a signal is generated from the position signal generation circuit 22 at the switch position of , and a signal corresponding to the positions of X ₁ and Y ₁ is output to the control circuit 25 . The control circuit 25 outputs the deviation of the position X ₁ Y ₁ from the center position X ₂ Y ₂ of the film 3, left 1 and top 1 signals to drive circuits 26 and 27, respectively. Drive circuits 26 and 27 rotate motors 16 and 12, respectively, so that film 3 moves to the right and downward by one-third of its lateral and longitudinal lengths. motor 12
The rotation of the motor 16 causes the platform 8 to move downward, and at the same time the rotation of the motor 16 moves the platform 13 to the right. Move on the axis. Next film 3
When enlarging and projecting another part of the image, operate the reset switch 28 to return the film 3 to its original position, and then specify the desired part with a magnetic pen.
In this embodiment, the number of loops of the conducting wire 17 is 3.
Although the combinations are shown here, any combination is possible. Further, the switches 18 and 19 are not limited to mechanical changeover switches, but may be switches based on electronic circuits.

[Effects of the Invention] As explained above, the overhead projector according to the present invention basically provides the following effects.

First, when there is a request to partially enlarge and project a specified position on the original film, the specified position can be easily specified by directly specifying any position on the original film using a predetermined position specifying means. Since the detection can be performed automatically, it is possible to effectively avoid the situation where the position designation operation becomes complicated when detecting the position of the original film.

Second, by cleverly combining the mirror Fresnel lens on which the original film is placed and the matrix-like conducting wires arranged in parallel below the mirror Fresnel lens, a position detection member is placed in the projection light path of the original film. Since the designated position of the original film can be detected without placing the original film, the quality of the projected image of the original film can be maintained at a good level while effectively avoiding the increase in size and complexity of the position detection member.

Third, since the matrix conductor wires are arranged opposite to the original film through the mirror Fresnel lens, it is possible to set the distance between the original film and the matrix conductor wires to be short, thereby increasing the resolution of position specification. It can be lifted up and the specified position can be detected accurately.

Fourth, because the specified position of the original film can be automatically aligned on the optical axis of the projection lens, the quality of the partial projected image of the original film can be maintained at an extremely high level without the need for manual alignment of the original film. be able to.

[Brief explanation of drawings]

FIG. 1 is a side view of an overhead projector to which the present invention is applied, FIG. 2 is a plan view of a film mounting table of the overhead projector of the present invention, and FIG. 3 is a position designation signal generator of the present invention. Circuit diagram: FIG. 4 is a circuit diagram illustrating the operation of the present invention. Symbol explanation, 2...Mirror Fresnel lens, 3...
...Film, 8,13...Platform, 2
2... Position designation signal generation circuit, 23... XY switch position signal generation circuit, 24... Judgment circuit.

Claims (1)

[Scope of Claims] 1. In an overhead projector that irradiates light onto the original film and projects an image of the original film onto a screen via an illumination light converging member and a projection lens, the original film is placed. a mirror Fresnel lens as an illumination light convergence member; a position specifying means having at least a magnetic material at the tip for specifying an arbitrary position of a document film placed on the mirror Fresnel lens; and a position specifying means disposed in parallel below the mirror Fresnel lens. two sets of conducting wires that intersect in a matrix pattern; a position detecting means for detecting the position of a matrix element where the mutual induction coefficient of the matrix-like conducting wires changes; An overhead projector comprising positioning means for positioning a specified position on the optical axis of a projection lens.