DE3400562C2 - Autofocus circuit for slide projectors - Google Patents

Abstract

An autofocus circuit for slide projectors with an electromotive adjustable film stage or lens is described, which is characterized by the fact that it recognizes glass-enclosed slides and unglazed slides and the lens or film stage is preset accordingly by the electric motor. In addition to the voltage of the differential photoresistor, the circuit also measures the photocurrent, which is much stronger with glazed slides than with unglazed slides. By providing reference currents and comparing the photocurrent with these reference currents, a voltage signal is obtained that is fed to a controller, preferably in the form of an OP amplifier, which sends a corresponding control signal to the motor controller and thus brings about the default setting for the slide being projected.

Description

a) the circuit contains a reference current source (11) for outputting fixed reference currents (Iatsdia; Ipappdä; hon ix »), which correspond to the partial current (Iphoto) if a glazed slide, an unglazed slide or if there is no slide in the projection beam path,

b) the circuit contains a comparator (12) for comparing the partial current (Iphoio) with the reference currents and for outputting a corresponding voltage signal, and

c) there is a transmitter (13) to which the voltage signal is fed, and in turn the controller (14) a corresponding control signal which causes the motor controller to set a preset that is matched to the projected slide to effect the film stage or the lens.

2. autofocus circuit according to claim 1, characterized in that the comparator (12) is optical Display means are electrically connected, which operate in accordance with the output control signal and show whether there is a glazed, unglazed or no slide in the projection beam path is located

3. autofocus circuit according to claim 2, characterized in that the optical display means (16) are different colored light emitting diodes.

The invention relates to a circuit for the drive motor for the independent adjustment of the film carrier or the lens to maximum image sharpness with slide projectors.

It is known in slide projectors to provide a device by means of which automatically the distance between the film to be projected and the projection lens for maximum sharpness of the projected image is set. For this purpose either the film stage or the projection lens are along the optical axis displaceable and driven by an electric motor.

The electric motor lies in an electrical circuit, the essential part of which is a differential photoresistor is. The latter is exposed to a light beam from a side of the slide Light source is thrown onto the slide and reflected from there onto the photoresistor on the other Side of the slide is attached Both the light source and the differential photoresistor are usually Arranged in a fixed position But either the light source or the photoresistor can either be connected to the Film stage or connected to the projection lens and can be moved together with these components

ίο be. Infrared light can preferably be used as the light will.

The control voltage for the electric motor is between the two parts of the differential photoresistor tapped. This voltage is only then opposite the two poles of the supply voltage the same size if the reflected light beam falls on the gap between the two partial photoresistors or both partial resistors are evenly exposed to light. Becomes one of the partial resistances more exposed to light than the other, so the two partial voltages of the Miiieiabgriffes are opposite the poles of the supply voltage are unequal, and this is used to start the motor and readjust the position of the film stage or the lens until the voltage is equal again prevails and thus again the maxima. '·? Image sharpness on the projection screen is achieved

These known autofocus devices work good and regulate the image sharpness reliably, if z. B. the slide "jumps" in a known way after it has stood in the projection beam for some time and has become warm

However, the manually preselected one is always used Object distance set between the reflection point on the slide and the projection lens, which is known in Way depends on the projection distance. Therefore, maximum image sharpness is only achieved when the reflection point is directly on the slide film, d. H. with unglazed slide «,

In the case of glazed slides, the point of reflection is not on the slide film but on the front of the covering glass panel. The object width is thus adjusted to the distance between the glass pane and the projection lens, and the slide film that is seen from the projection lens behind the glass pane is outside the object distance and is therefore shown blurred on the projection screen. (On the other hand, the dust, fingerprints and other uncleanliness that arise

so possibly located on the glass, which is understandable is highly undesirable)

In itself, this difference in the position of the reflection point and the actual slide film would not be particularly significant problematic, because if it were ensured that only glass slides were projected, so this difference could be entered into the circuit as a fixed value and thus taken into account accordingly will.

However, it is by no means always guaranteed that only ever glazed slides, or always only unglazed ones Slides are projected, but in many cases it is almost the rule that unglazed and glazed slides are projected into each other. It must therefore be the position of the film stage or the lens in the one Case to be settled in a different place than in the other case.

This adjustment to the respective required location can e.g. B. depending on the amount of over the

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Differential photoresistance of flowing current happens This current level or strength is - independent on the voltage distribution between the two partial photoresistors - be higher when that on Light hitting the photoresistor is reflected off a glass surface as if it were from the actual Film layer is reflected.

It is therefore from various publications, e.g. B. from DE-OS 31 20 816, but also from DE-OS 20 10 401 and US-PS 44 15 244 known to the current flowing through the differential photoresistor measure in order to distinguish glazed from glassless slides and the film stage or the lens a corresponding one To give preset. Depending on the level of this current, the setpoint is the Autofucus circuit changed so that the autofocus motor is operated until the voltage of the differential photoresistor reaches the changed setpoint has reached.

Since this comparison takes place on a sliding scale, it is However, a disadvantage of such circuits is that the display means for what type of slide is currently being projected cannot be operated as there are clearly defined voltages for the projection of a glass slide and an unglazed slide are not specified.

The invention is based on the object of an autofocus circuit to specify for slide projectors, in which it can be easily distinguished whether straight a glazed slide or an unglazed slide is projected, or whether no slide at all is in the beam path and can be easily connected to if necessary.

This task is solved by a circuit, soft has the features specified in claim 1 Details of the circuit are in the subclaims specified.

The current flow with a glazed slide, with unglazed slide and with no slide at all in the beam path can be determined empirically, and according to the invention, a reference current source is provided in the circuit, which emits corresponding clearly defined reference currents in accordance with the agreement established by him, emits a likewise clearly defined voltage signal to a transmitter, to which the voltage tapped by the photoresistor is also fed, and which in turn sends a corresponding control signal to the controller of the electric motor which is matched to the type of slide used. If there is no slide in the sirahlengang, the control signal can be used to shut down the autofocus control as a whole.

The clearly defined voltage signal coming from the comparator can now be added according to the invention can be used to control display means, e.g. B. in the form of different colored light emitting diodes, so that the user it is optically indicated which type of slide is currently in the beam path

In the drawing, the invention is in one embodiment in which the autofocus light source and the differential photoresistor are both with connected to the lens. Show it

Fig. La and Ib the position of the lens at maximum Image sharpness for differently framed slides, and

F i g. 2 is a block diagram of the invented autofocus circuit.

In FIGS. 1 a and 1 b, 1 denotes the slide film, which stands in a projection beam path which defines the optical axis 2. A projection lamp 3 and a projection objective 4 are also arranged on this axis. The latter projects an image of the slide film 1 onto a projection screen (not shown) located in the direction of the arrow B. The objective 4 is axially adjustable in a carriage 4a, which in turn is from

ίο a motor 15 (Fig.2) along the optical axis is movable

5 denotes a light source behind a slit 6 which throws a light beam 7 onto the slide Light beam is reflected on the slide and reaches a differential photoresistor 8, the electrical part the control circuit of the electric motor 15 is the light source 5 and the photoresistor 8 are fixed to the Carriage 4a connected.

In Fig. La, the slide film 1 is held in a cardboard frame 9, without a cover /: ie the glass pane and can be seen in the plane of the film stage FS. It is assumed that an object distance A between the objective 4 and the slide film 1 must be maintained for a sharp image of the slide film 1 on the projection wall. In this position of the slide film is 7 reflected 1, the light beam centered on the differential photoresist 8, the position change of the slide film 1 along the optical axis 2 of the distance A out, so one or the other part of the resistor 8 is more or less illuminated This ultimately causes the electric motor 15 to work and to move the lens until the slide film 1 is at distance A again
Instead of being in a cardboard frame without glass panes, the slide film 1 can, however, _e.g. B. can also be contained in a plastic frame in which the film is covered on both sides with a pane of glass 10a, 10Z>, each of which is an integral part of its frame half. These glass panes usually have a thickness d ~ 0.9 mm.

If such a slide is now broken into the beam path (FIG. 1b) and the slide film 1 is also in the plane FB, the light beam 7 is no longer reflected on the slide film 1 but on the front of the glass pane 10a . The reflected beam now no longer hits the photoresistor 8 symmetrically, but the photoresistor is illuminated asymmetrically. As a result, the voltage U _p hoio tapped at the photoresistor for the motor control drops. This causes the motor 15 to start up and move the carriage 4, with the tendency to relocate the reflection point symmetrically to the optical axis or to the photoresistor.

Without the invented circuit, the slide 4a would be displaced to the right by ie distance d in the illustration of FIG. 1b up to the position shown in dashed lines. The distance between slide film 1 and lens 4 would then be A + d, and slide film 1 would thus be outside the plane of focus

oü lie.

The invented circuit does, however. d -. \ 3 this shift takes place only partially. In fact, the slide has only been shifted by a distance As. According to the laws of geometrical optics, the glass pane 10a brought into the beam path extends the distance A by a distance As which is approximately 1/3 of the thickness d of the glass pane 10a. The exact value of

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Ace is

- (■ -ν)

d.

where η 'is the refractive index of the glass and π the refractive index of the surrounding medium. The glass pane iOb does not play a role in this consideration.

The objective 4 must be moved further away from the slide film 1 by this distance As- l / 3c / so that in comparison to FIG. 1 a optically the same spacing conditions prevail and the film 1 is shown in focus on the projection screen.

At the distance A + Js , the reflection of the light beam 7 does not take place at the level of the optical axis, but outside it at point C, and thus the photoresistor 8 remains illuminated asymmetrically and supplies a lower voltage • Jphunr - ■? fcr.sncung ccs.c ..; only, as. in, to supply the Otuci cm voltage signal, which in this case has the same size as Uphom because then the controller controlled by the encoder and with it the motor 15 remain in the idle state.

This voltage signal is obtained by measuring the photocurrent Ιρ, ^, ο and should now be based on FIG. 2 will be explained. In Fig. 2 again shows the differential photoresistor 8, between the two partial resistances of which the voltage tap Uphoio takes place. In addition, the photocurrent Iphoro is tapped at point D.

The circuit assumes that significantly more light is reflected on the glass pane 10a (FIG. 1b) than on the Slide film 1 itself (Fig. La). When projecting a glazed slides, the photoresistor 8 is therefore exposed to increased light intensity, which leads to flow a stronger current through this resistor. For the strength of the flowing current there is the Resistance value of the individual partial resistances, d. H. the symmetrical or asymmetrical exposure of the Differential photoresistor is irrelevant, the only thing that matters for the current is the illuminance on the total resistance.

This illuminance and thus the strength of the photocurrent when projecting a glazed and an unglazed slide can be determined empirically, and corresponding reference currents 1gu «ju, Ip, _PP di * and / * <.," O "are provided in a reference current source 11. These reference currents on the one hand and the photocurrent Iphoto on the other hand are fed to a comparator 12. The comparator determines that the photocurrent corresponds to one of the reference currents and outputs a corresponding voltage signal Up, _pp d * -. Ugusdii or Ukan Di ₃ to a transmitter 13, which is designed as an OP amplifier. According to this voltage signal, the OP amplifier in turn sends a control signal to the regulator 14 of the electric motor 15, which adjusts the lens slide accordingly.

For explanation it is assumed that the resistor 8 is illuminated symmetrically in a cardboard slide in the film stage and thus supplies the greatest voltage Uptoto. However, IpI ₁₀₁₀ is lower for a cardboard slide than for a glass slide. Nevertheless, the comparator 12 delivers the highest voltage signal Up _ipp di ^ "If the comparator" detects "that a glass slide has been inserted, it delivers a lower voltage signal Uc-hsds- The OP amplifier, ie the regulator 13, receives this lower voltage signal Uoiuia is supplied, in turn sends a control signal to the motor controller 14 until the motor 15 has moved the slide 4a into a position in which the voltage tapped at the resistor 8 is equal to the voltage signal Ucii% dii . This is the case when the resistance 8 is asymmetrically illuminated in the manner shown in Fig. Ib manner, characterized in that the slide 4a occupies the extended position in which the lens 4 at a distance A + Js from the slide film 1 with lens 4 stands away.

Hence: By looking at the level of the voltage signal

ίο determined, one also determines the amount of displacement of slide with lens.

It also follows from this, however, that in the case of a cardboard slide being projected, the photoresistor 8 is not necessarily must be illuminated symmetrically. It just has to be for that

it must be ensured that the voltage signal l) p, _PP dm is exactly as large as that voltage U _p i, oi,>. which the resistor 8 with an inserted cardboard slide and setting of the slide 4a to the middle of its displacement weight / säbgibi. Whether or not the resistance S is actually illuminated symmetrically is secondary. The whole thing is just a question of balancing.

There is no slide in the optical path, so no reflection and hence no lighting is the differential photoresistor 8. The latter remains high impedance and thus corresponds to ₀ U _p no, about the Versorgungsspanniing. Therefore, if the voltage signal UkcinDiM is about the supply voltage to the OP amplifier; «R, no control signal is output for the motor control 14, ie the latter is shut down.

After the carriage 4a has been preset by the control signal output by the OP amplifier, any change in the position of the slide film 1 or the glass slide causes a change in the voltage Uphoto in a known manner, which is used to output a control signal from the OP amplifier the motor control 14 leads, ie the normal function of an Aiitofocus circuit comes into effect and regulates the lens in a known manner in the preset position for the purpose of automatically maintaining the focus.

In addition, in the described embodiment of the circuit there is also an optical indicator 16 for "Glass slide", "unglazed slide" and "no slide" provided. The indicator 16 is also controlled by the voltage signal of the comparator 12 controlled and causes the display by lighting up different colors LED.

Finally, the electric motor 15 can also be separated from the autofocus circuit by means of a changeover switch 17 and switched to manual focusing.

It should be noted that, although the invented circuit is here based on an embodiment is explained in which the light source 5 and the differential photoresistor 8 with the lens 4 are connected, the circuit is of course also applicable when the light source 5 and the resistor 8 both arranged in a stationary manner or only one of these components with the lens or with the film carrier are connected.

Finally it should be mentioned that the function of the autofocus circuit is mainly only for slides in cardboard frames is necessary in order to maintain the image sharpness even when the slide film by the warming in the Projektäonsstrahiengar.g "jumps" in the familiar way.

Since the film is held between two panes of glass in glass slides, it has no way of jumping.

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or at most in areas of approx. 0.1 mm to each side, which does not cause any noticeable blurring of the projection image. At Giasdias the autofucus circuit is used therefore mainly to effect the preset discussed above once you have disregards the fact that the glass slide in the guide of the film platform occasionally wobbles, which is then caused by the Autx / focusing is compensated.

For this 2 sheets of drawings ok

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Claims (1)

34 OO 562 claims: 1. Aatofocus circuit for slide projectors with an electric motor to move the film stage or the lens along the optical axis, with a differential photoresist, which is of a emitted by a light source and reflected on the slide in the projection position Light beam is applied, furthermore with a voltage tap on the differential photoresistor due to its voltage relative to the two poles of the supply voltage of the electric motor is switched to clockwise or counterclockwise rotation or stopped, and with a power tap for tapping a partial current proportional to the photocurrent flowing through the differential photoresistor, which is used to recognize the type of frame of the projected slide through through the following features: