DE2856307A1 - Exposure control for SLR system camera - has circuit controlling setting signal so that same results are produced for same conditions irrespective of max. aperture of lens fitted - Google Patents

Abstract

The full aperture TTL metering for the SLR system camera has a special control circuit which maintains the shutter speed setting when the lens is changed for a different type having a different max. aperture. This is realised by using a main control signal duly regulated for each lens type. The system ensures that scenes with similar exposure factors provide the same automatic set shutter speed, irrespective of the lens fitted. As the shutter release button is pressed the power source switch (SM) is closed to supply the whole circuit from the camera battery (E1). A photo-diode (PD) receives the light through the lens. Its output signal is amplified by an operational amplifier (OP1) and logarithmically suppressed by a diode.

Description

Exposure control for a camera

The invention relates to an exposure program control for a Camera.

An exposure program control is already in the field of photographic cameras has been proposed in which the coming from the object and through the aperture at maximum opening is measured, followed by the shutter speed based on the brightness information thus obtained the subject and also according to a program that is programmed so that it is both the value of the opening cover and the shutter speed for the control range from the maximum aperture changes to the minimum aperture, and finally the membrane as a function of from the shutter speed determined in this way is controlled to under given Conditions to ensure the optimal exposure value.

However, it has been found that this type of exposure program control leads to difficulties when using photographic lenses with different maximum Apertures are used as interchangeable lenses in a camera that is equipped with the control is provided. Since the program curve always changes when that When the lens is exchanged, it is impossible to use the same combination of shutter speeds and the aperture for the same exposure value (Ev). A change of the lens always leads to a difference in the combination due to the Difference in the maximum aperture. This is for the user of the camera extremely uncomfortable.

The aim of the invention is therefore an exposure program control for a camera that does not have the above-mentioned inconveniences.

The invention is intended in particular to provide an exposure program control for a camera that makes it possible to always use the same combination from the shutter speed and the aperture opening for the same exposure value Ev obtain.

A particularly preferred idea of the invention consists in an exposure program control for a camera in which a device is provided which a predetermined signal controls the shutter speed that is then determined according to a program If the photographic lens corresponds to the Camera through one Lens is replaced, which has a different maximum aperture, controls this device the predetermined signal in such a way that for the same exposure value, determined by the aperture and the shutter speed are always the same shutter speed determined by the program regardless of the difference in the maximum Aperture opening of the lens, which is attached to the camera, results.

In the following, a preferred one is based on the associated drawing Embodiment of the invention explained in more detail: FIG. 1 shows a program diagram an example of a program of shutter speed used for one embodiment the control according to the invention can be used.

Fig. 2 shows the mechanical structure of the diaphragm control according to one Embodiment of the invention in partial views and in detail, wherein, seen of the camera, Fig. 2A shows a side view from the left, Fig. 2B shows a side view from the right and FIG. 2C shows a view from below.

Fig. 3 shows in a circuit diagram an embodiment of the electrical Circuit for an embodiment of the exposure program control according to the invention.

An example of a program in individual described, which in an embodiment of the inventive Control can be used.

The program shown in Fig. 1 is suitable for cameras with interchangeable lenses, in which the light passing through the lens is measured in order to achieve an optimal To deliver exposure value. In the typical case, to generate the in Fig. 1 The program curves shown are related to two objectives, one of which is a maximum Has an aperture value of F 1.4 and a minimum aperture value of F 16 and below is referred to as lens A, while the other has a maximum aperture value F4 and has a minimum aperture value F32 and is referred to as lens B in the following will. As shown in Fig. 1, each program curve consists of three different ones Divide, namely the section x, the section y and the section z. The section x is the area in which, with an increase in the exposure value Ev, only the The shutter speed changes while the aperture value remains at the maximum value. Of the Section y is the area in which both the shutter speed and the Aperture value within the intermediate aperture range from the maximum to the minimum aperture value change. In section z, only the shutter speed changes, while the aperture value remains at the minimum value.

As shown by a solid line in Fig. 1, overlap According to the invention, the section y of the program curve for the objective A and the Section y for the lens B. The result is therefore always the same combination from the shutter speed and the aperture value for the same exposure value Ev, itself when the interchangeable lenses have different maximum aperture values.

A mathematical relationship for section y can be found in the following Manner, whereby for the sake of simplicity the APEX system Av, Tv, Ev, Bv, Sv will be used in the following.

The following equation generally applies to section y: Tv = c (Av + T (1) where sp and are constants.

The equation of optimal exposure in the APEX system, on the other hand, is known as Av + Tv = Bv + Sv.

Substituting this relationship into Equation 1, we get: Tv = 1 + to (Bv + Sv) + <In this way, the shutter speed Tv can be determined which is controlled by the brightness of the object Bv, which in turn is measured by a photo element.

However, with a system with internal measurement it is impossible to determine the value Bv itself to be measured exclusively. The output signal of the measurement, which is also called Measurement output signal is designated and is output from the photo element, is therefore to information that the value Av of the used interchangeable lens at maximum Includes aperture value Avo. Namely, the output signal of the photo element becomes the same Bv - Avo. Substituting this value for Bv into equation 2) results in: Tv = 1 & i (Bv - Avo + Sv) + 1 r This means that the value Tv depends on on the maximum aperture value of the lens used, i.e. depending on the Value Avo, is variable even if the brightness Bv of the object and the Film speed Sv remain at the same values as before. In this If the Av changes with the value Tv. As a result, for the same values Bv and Sv, namely for the same exposure value Ev, the combination of the values Tv and Av with the The difference in value Avo between the interchangeable lenses used changes. The dash-dotted one Line B 'in Fig. 1 shows this relationship. The curve B 'of the lens B runs parallel to the curve of objective A and at a distance from the curve of objective A, which corresponds to the difference in value Avo between lenses A and B, the in the example shown is 3, since the value Avo of lens A is the same Is 1 and the value Avo of lens B is 4.

About this unfavorable influence of the individual maximum aperture value To eliminate Avo on the program curve, according to the invention, the information using the maximum aperture value of the individual lens in the above equation (3) introduced so that the following equation results: Tv = 1 (3v + Sv - Avo) + 1 («Avo +) (4) As indicated by a solid line B in Fig. 1, Thus, according to the invention, the two program curves of the two different ones overlap Objectives A and B correspond to each other with respect to section y by drawing one of the curves in Direction of the Tv axis is shifted parallel.

In Fig. 2A is a camera housing 9 with a lens 9a and a Mirror box 10 shown. When the shutter release button, not shown is pressed, move an upper pawl 11a and a lower pawl lib with the shutter release button downwards, so that a shift lever 12 is opposite rotates clockwise about its axis 133 against the force of a spring 144 while a shift lever 16 also moves counterclockwise around its axis 17 rotates against the force of a spring 18. This has the consequence that the pawl part 13a a shutter operating lever 13 released from the switching part 12a of the switching lever 12 will. Well can the shutter operating lever 13 clockwise about its axis 20 together with the dimming lever 14 under the action of a spring 15, which is attached to the lever 14. The dimming lever 14 is not used to operate the aperture blade shown, which is attached to the lens 9a. In In the first phase of the above-mentioned rotary movement, a switch S1 is opened. The rotary movement of the lever 13 also causes an intermediate lever 21 to move in opposite directions rotates clockwise by engaging a pin 13c on lever 13. This rotary movement of the lever 21 is transmitted to a sector lever 23 via an intermediate shaft 22 as shown in Fig. 2B. Part of the sector lever 23 is designed as a toothed strip 23a. The rotation of the rack 23a is on a ratchet wheel 29 transmitted, -after the speed of rotation is translated by gears 26, 27 and 28 has been.

On the other hand, when the shift lever 16 is rotated by If the shutter release button is pressed in the manner described above, a Lever 51 released from engagement with switching part 16a of lever 16. Of the Lever 51 therefore begins counterclockwise around its axis 52 under the Effect of a spring 53 shown in Fig. 2C to rotate. The lever 51 has a Toothed strip 51b which meshes with a gear 55. The gears 55, 56 and 57 and a flywheel 58 together form a delay device whose function consists in delaying the work of the lever 51. There is a pin 56a on the gear 56 is withdrawn by turning clockwise in the early stage of the work of the lever 51 rotates, a lever 59 can rotate about its axis 60 under the action turn a spring 61 counterclockwise. This movement, in turn, leads to the fact that a retaining lever 63 is clockwise about its axis 64 under the action a spring 65 rotates, so that the holding force exerted thereon is removed from the lever 30 to push it against an electromagnet Mg1 shown in Fig. 2B is.

As it is described in more detail below, however, is already in the first step of pressing down the shutter release button of the power source switch SM has been turned on, so that the solenoid Mg1 has been excited since then is. Even after the mechanical holding force has been removed from the lever 30, pulls the electromagnet Mg1 continues the iron piece 34 of the lever 30 so that this is held immobile.

When the dimming lever 14 is under the action of the spring 15 in the Moved down in the manner described above, the aperture of the lens is beginning from the maximum aperture, gradually dimmed in a known manner. to the point in time at which the aperture just stopped down to the optimal value is, the electromagnet Mg1 is de-energized via an electrical circuit like it will be described later. As a result, the iron piece 34 from the electromagnet is released and the lever is turned counterclockwise under the action a spring 32 can rotate. In the course of this rotary movement, the pawl 30a comes of the lever engages the ratchet wheel 39 to lock it.

Another movement of the lever 51 to the left in FIGS. 2A and 2C leads to the fact that a lever 101 turns clockwise about its axis 102 against the Force of a spring 103 rotates, since in the last phase of the rotary movement of the lever 51 this comes into contact with a part 101a of the lever 101. As a result of the rotation of the lever 101, a lever 104 is released from the lever 101, so that the lever 104 can rotate clockwise under the action of a spring 105. In the first phase This rotary movement of the lever 104 opens a pin 104a attached to the lever 104 a switch S2. As the lever 104 continues to move, the lever pushes upwardly a pin 106 attached to a mirror support member so that the mirror is rotated upwards about an axis 107. When the lever 104 is in rotates in the manner described above, a lever 108 opposite clockwise about its axis 109 counter to the force of a spring 110 by a Pin 104b of lever 104 rotated. At the end of the rotation of the lever 104, a shutter release lever becomes 111 down to release the shutter.

After a given exposure time and after the end the movement of the rear membrane of the focal plane shutter starts a signal lever 112 of the shutter move down, causing a lever 115 clockwise rotated about the axis 116 against the force of a spring 117 via an intermediate lever 113 will. This leads to a release of the lever 118 from the lever 115, so that a lever 119 clockwise about its axis 120 under the action of a spring 121 in FIG. 2C turns. As shown in FIG. 2A, a part 119a of the lever 119 is in engagement with a pin 118a, which is attached to a lever 118, this lever 118 rotated counterclockwise. In the early phase of the rotary movement of the Lever 119 comes one end 119b of the lever into contact with a lever 63 to turn it counterclockwise. The ratchet wheel 29 is therefore of the pawl 30a of the lever 30 is released. Another rotation of levers 118 and 119 brings a pin 118b on lever 118 into contact with levers 104 and 13, so that the system consisting of elements 21, 22, 23, 26, 27, 28 and 29 in the in Fig.

2 starting position shown on the intervention with the levers 118, 119 and 13 is returned. Since the pin 106 is in its starting position is returned under the action of a spring, not shown, moves the mirror down. Since at the same time the lever 14 returns to its original position, the shutter can also return to its open position.

In this way, a photographing operation is completed.

By subsequently actuating a film transport lever (not shown) the pin 122 moves in a known manner, the one with the transport lever is locked clockwise and the lever 51 is in the position shown in the drawing Position returned. Then the pin 123 moves clockwise, whereby the levers 119 and 118 returned to the position shown in the drawing will.

Based on Figure 3, the electrical circuit of a Embodiment of the invention in connection with that shown in FIG Program diagram described.

The power source switch SM shown in Fig. 3 is thereby closed that the shutter release button is pressed. Before pressing the The shutter release button is on top of the lens aperture ring smallest aperture value, i.e. to the value F 16 for lens A and to the value F 32 set for lens B. In the first phase of the actuation movement the shutter release button down, the power source switch SM is closed and the entire circuit is supplied by the energy source cell El. A photodiode PD receives the light that goes through the lens and aperture and creates one Photocurrent, the intensity of which is directly proportional to the intensity of the received Is light. The photocurrent generated in this way is passed through an amplifier OP1 and a diode D1 logarithmically suppressed. About the temperature characteristics of the diode D1 are a constant current source CC1 and a diode D2 intended. Up to this stage of work, the previous ones based on 2A to 2C described levers 12 and 16 not yet moved, so that the dimming lever 14 is held by the lever 13 in a position in which the aperture is fully open is. This position corresponds to the position shown in FIG. 2A.

In this position, the amount of light falling on the photodiode PD has a value that results from the fact that the information about the maximum aperture value with the aperture fully open from the light information of the object is deducted. This value can after a logarithmic suppression in the APEX system can be played with Bv - Avo. At the input of the amplifier OP 1 there is a constant voltage circuit E2 is a voltage corresponding to the information on the film speed Sv. The voltage appearing at the output terminal A of the amplifier OP1 is therefore VA equal: VA = (Bv + Sv - Avo) (5) This voltage at point A is determined by the resistors -R1 and R2 shared. The resistance ratio of resistor R1 to resistance R2 is preselected to be equal to 1+ in equation (4). The tension at the connection point of the two resistors R1 and R2 is therefore equal to 1+ «(Bv + Sv - Avo). This tension is connected to amplifier OP2 via switch S1. The information 1 + a & (Avo +7) via a constant current source CC2 and a variable resistor R3 added to the voltage. The voltage VB appearing at the output terminal B, is therefore equal to: VB + 1 i ob (Bv + Sv - Avo) +11+ «(« Avo + t) (6) This corresponds the value Tv of the equation (4).

The resistor R3 shown in Fig. 3 is in connection with a Movable pen or similar device on the individual interchangeable lenses, inserted into the camera.

When the lens is replaced, the resistance value changes of the resistor R3 as a function of the maximum aperture value of the lens, that is used. In this way, the Avo value of the second expression becomes 1 (okAvo + #) in equation (6) by the variable resistance R3 for each interchangeable lens changed with another maximum aperture. These Function of the mutable Resistance R3 ensures that section y of the program curve for a lens and each other for the other lens with a different maximum aperture overlap and that always the same combination of shutter speed and aperture value for the same value Ev is given as far as section y is concerned. The voltage VA at point A thus represents a value Tv which is the condition of optimal exposure at the maximum aperture value, i.e. that the voltage VA has a value Tv in section x of the program curve. The voltage VB at point B gives one Value Tv at the overlapping section y of the program curve again. The voltage VA is present continue to the comparators CP1 and CP3 via a switch 82, whereas the voltage V3 is connected to the comparator CP1.

The following describes the operation in the case where the shutter speed for a given brightness of the subject on the section y of the program curve.

Depressing the shutter release button further will cause levers 12 and 16 disengage as described above loosen and that then the dimming lever 14 is set in motion to open the aperture stop down the lens. Before stopping down, however, switch S1 opens and becomes the voltage at the junction of resistors R1 and R2 in the capacitor C1 to set the voltage VB.

As the aperture gradually fades out over time, the Amount of light incident on the photodiode PD at any point in time during the dimming to a value that is given by the fact that the information about the actually at this point the aperture stopped down from the brightness of the subject is deducted at the same time. The output voltage VA of the amplifier OP1 will therefore be the same Bv + Sv - Av, which represents a value Tv that satisfies the condition of optimal exposure and the information about the aperture value at that time corresponds. The voltage VA and the voltage VB in the capacitor is stored are compared with each other in the comparator CP1. When the tension VA becomes equal to voltage VB, the logic level of the output signal comes from Comparator CP1 to the high level. At this point it becomes an electromagnet Mg 1 flowing current is interrupted, so that the front end 30a of the lever 30 in the pawl of the ratchet wheel 29 is detected in order to set the dimming lever 14. The dimming movement is thus stopped. Then a lever 104 rotates, to open switch S2. This stores the voltage VA in the capacitor C2. The voltage VA stored in this way forms an input signal of the comparator CP3.

The mirror moves up and the lever 108 releases the lock the end. By the time the front diaphragm of the breech starts to move, the trigger switch S4 opens and becomes a circuit for the logarithmic Time translation put into operation, which has an amplifier OP4, a constant voltage circuit E3, a capacitor C3, diodes D3 and D4, a resistor R5 and a constant current source CC4 includes. The conversion circuit supplies a voltage that corresponds to the exposure time which begins with the beginning of the barrel of the front membrane of the breech.

At the time when there is a match between this value Tv and the previously stored voltage VA occurs, the comparator CP3 becomes effective, to de-energize the electromagnet Mg 2. Now the rear membrane of the closure begins to run and moves the signal lever 112, which is shown in Fig. 2A, after The associated mechanical components of the device operate in the foregoing described way. In this way the recording of a picture is made on a film frame completed with the optimal exposure according to the program curve shown in FIG.

In the above, the operation of the device has been described in detail for the case where the shutter speed is on the section y will be described.

In the case where the brightness of the subject is low, can optimal exposure can also be obtained in the following manner. In this case triggering the shutter never leads to a change in the aperture. The aperture remains at its maximum value when the aperture is fully open and instead, only the shutter speed changes along section x of the program curve, to provide optimal exposure. The other working steps of the device in this case correspond to the work steps described above for the case the control along section y of the program curve and are therefore not repeated shown in detail in the case where the brightness of the object is great is, an optimal exposure can also be obtained in a similar manner. In this case, when the shutter release button is pressed, the aperture will open stops down to the smallest aperture value and then only changes the shutter speed along section z of the program curve in order to achieve optimal exposure under the to deliver given photographic conditions. The other steps of the control function correspond to those described above and do not have to be shown again.

Claims (6)

Exposure control for a camera PATENT CLAIMS 1. Exposure control for a camera with a measuring circuit for measuring the light of an object, that goes through the aperture of a photographic lens at its maximum Aperture value is set, with a circuit that generates a predetermined signal, that corresponds to the shutter speed determined by a program that is programmed to do so is that it changes both the shutter speed and the aperture value of the output signal of the measuring circuit changes as long as the aperture value is in the range from the maximum aperture value to the minimum aperture value, with one Device which determines an aperture value in response to the specified signal, which is suitable for optimal exposure and with an aperture control device for stopping down the aperture according to the determined aperture value, g e -k e n n z e i c h n e t by an adjusting device for controlling the predetermined signal depending on the maximum aperture value of the photographic lens that just attached to the camera in such a way that even if there is a difference consists in the maximum aperture value between the photographic lenses, which is optional and interchangeably attached to the camera, the shutter speed that is after Program, always remains at the same value as long as the exposure value, which is determined by both the shutter speed and the aperture value, remains at the same value. 2. Exposure control according to claim 1, characterized in that g e -k e n n z e i c h n e t that the actuator is controlled by the movement of the photographic lens locked when attached to the camera and arranged to provide a Control according to the maximum aperture value of the attached photographic Lens causes. 3. Exposure control according to claim 1, characterized in that g e -k e n n z e i c h n e t that the measuring circuit generates a first signal, which in the APEX system is represented by equation 1 (Bv + Sv - Avo), where i is a constant, Bv is the information about the brightness of the object, Sv is the information is about the film speed and Avo is the information about the maximum aperture value is. 4. Exposure control according to claim 3, characterized in that g e -k e n n z e i n e t that the circuit that the given Signal generated, generates a second signal which is the sum of the first signal and a predetermined one Corresponds to the value given by the equation 1 + d ((.Avo, where T is a constant. 5. Exposure control according to claim 4, characterized in that g e -k e n n z e i c h n e t that the measuring circuit when the diaphragm through the work of the diaphragm control device is dimmed, a third signal is generated which is represented by the equation Sv + Sv - Av is reproduced, where Av is the information of the aperture value in the APEX system. 6. Aperture control according to claim 5, g e k e n n z e i c h -n e t by a circuit (CP1) which compares the third signal with the second signal and applies its output signal to the device which determines the aperture value.