DE3206792A1 - CAMERA WITH AUTOMATIC DISTANCE ADJUSTING DEVICE AND AUTOMATIC EXPOSURE CONTROL DEVICE - Google Patents

Description

The invention relates to a camera with an automatic Distance setting device and an automatic exposure control device, in which the coordination control alternates with an electromagnetic Facility works (time-sh / aring operation).

In cameras it is known to automatically use the lens to set a distance measuring device, which is based on the actuation a shutter release responds, whereupon it emits a distance adjustment signal until the lens is in the in-focus position is moved; such automatic distance adjusters are very diverse Wise trained. It is also common practice in such cameras to automatically control exposure. Therefore, when a picture is to be taken, it is only necessary that the photographer set the distance measuring area in

Deutsche Bank (Munich) KIo 51/61070

Diosdner Bnnk (Munich) Klo 3Ό9844

Postal check (Munr.honl KIo 670-43-004

Field of view of the viewfinder with the part of the picture to be recorded Object that is to be in focus, before he pulls the shutter release, so that it is thereby becomes possible to take focused pictures with the correct exposure.

However, in order to ensure that the image is optimized with such a camera, it is necessary that, after the lens is stopped exactly in the focused position, the shutter release is initiated will. In the prior art, this problem has been solved by providing a timer circuit that a signal after a certain time after the start of an automatic distance adjustment operation (hereinafter referred to as AF process) generated, and that a release of the shutter by this signal of the Timer circuit and a signal representing the completion of the AF operation is allowed; this is in the disclosed Japanese Patent Application 55-40438, which corresponds to U.S. Patent Application 74313 filed September 11, 1979. However, in this method, power is supplied to a shutter release actuator or to an electromagnetic device when the signal from the timer circuit and the AF termination signal occur simultaneously, it follows that if for any reason the AF operation takes a long time and this time exceeds the time set on the timer circuit, the start of the shutter cycle occurs at the same time that the AF operation is ended. In other words, is at this procedure in the above-described case allowed the termination of the power supply an electromagnetic device that controls the AF process, and · the start of power supply to another electromagnetic device that controls the shutter operation, take place at the same time; if this procedure is so on the control of AF processes and shutter sequences with just one electromagnetic device.

is turned, incorrect processes result.

In controlling the AF operation and the shutter operation with the common electromagnetic device it is to be taken into account that the beginning and the end of the AF operation by starting the power supply to that electromagnetic device and terminating it the power supply can be controlled in a first time range, and that. the beginning and the end of the closure process by starting the power supply to the electromagnetic device and ending the power supply can be controlled in a second time range. However, if it happens to such a camera that the termination of the power supply of the control of the AF operation without a time delay is followed by the start of the power supply of the control of the shutter operation, the The electromagnetic device does not perform the necessary action to end the AF process and the AF device (automatic focuser) does not work accurately and reliably.

In another system, if the AF operation and the shutter operation are sequentially controlled in time, ^{ΔΌ since a drive plate is} stepwise moved by the control of the power supply to an electromagnetic device, assuming a situation as described above, the problem arises that that not only the AF process can be stopped, but that the

the following processes are not carried out.

Taking into account the above, it is an object of the invention to provide a camera with an automatic

Distance setting device and an automatic loading 35

to create lighting control device in which there is a coordination control makes possible that 'only one electromagnetic device, the AF process and the shutter process controls, whereby a highly accurate and.precise

automatic distance adjustment and exposure control possible are.

The invention is described in more detail below on the basis of exemplary embodiments with reference to the drawing. Show it:

FIG. 1 shows a plan view of an embodiment of a camera which is provided with an automatic distance setting device according to the invention and an automatic exposure control device according to the invention, the rest position being shown when the camera is ready to take a picture.
15th

Figure 2 is a similar view to Figure 1, but in one other position in which a distance measuring process is initiated,

Figure 3 is a similar view to Figure 1, but in one

other position in which the armed state ■ is recorded,

Figure 4 is a view similar to Figure 1, but in one other position in which exposure control is initiated,

Figure 5 is a view similar to Figure 1, but in one another position in which the exposure control is ended,

Figure 6 is an electrical circuit diagram of an actual example of a control circuit in an inventive one Camera,

FIG. 7 shows a pulse / time diagram which explains the mode of operation of the circuit according to FIG.

FIG. 8 shows an electrical circuit diagram of a further example of a control circuit in a device according to the invention Camera,.

FIG. 9 is a pulse / time diagram which explains the mode of operation of the circuit according to FIG.

In Figures 1-5, 1 is a magnetic yoke that is attached to a

XO not shown shutter base plate or the like attached rst; 2 is a solenoid which when energized by a "control circuit described later" generates a magnetic field generated. The magnet yoke 1 and the solenoid 2 constitute one Drive magnet. 3 is an armature which is attracted to the yoke 1 when current flows through the solenoid 2. Of the Armature 3 is held on and acts as a unit with a control lever 5 which is pivotably attached to an axle 4 which is attached to a shutter base plate. A spring 6 acts on the control lever 5 in the opposite direction clockwise in the drawing. A drive plate 7 is movably supported by the pin 4 and a pin 8 and urged by a spring 9 to the right in the drawing. An opening lever 10 is pivotable on a Fastened pin 11, which is attached to the drive plate 7 is and is acted upon by a spring 12 counterclockwise in the drawing. 13 is a shutter blade, the ■ is pivotally mounted on a pin 14, the is attached to the not shown shutter base plate. It should be noted that it is in actual execution another shutter lamella or another shutter curtain is movable symmetrically to the first, but omitted in the drawing for the sake of clarity is. The shutter lamella or the shutter curtain has a slotted section in which a pin 16 engages, which is attached to an opening and closing lever 15 is and which is designed so that the shutter blade 13 with the opening and closing lever 15 together.

-δι

works. The opening and closing lever 15 is pivotable a pin 17 attached to the not shown Base plate is attached and is acted upon by a spring 18 counterclockwise in the drawing. 13a is a light sensor aperture that is integrated as a unit with the shutter blade 13 works. A locking lever 19 is pivotally attached to an axis 20 which is attached to the not shown Base plate is fixed, and biased by a spring 21 counterclockwise in the drawing. One AF control plate 22 is guided by pins 23 and 24, which are attached to the base plate, not shown, of a Spring 25 is biased to the left in the drawing and is designed to work with a speed adjuster known construction cooperates, which is rotatably attached to a fixed axis 27 Escapement wheel 26 is. An armature 28 is pivotally mounted on a fixed axle 29 and works with the ratchet wheel 26 together. 30 is a lever for a light projection element, which is attached to an axis 31 that is not attached to one shown camera body or the like is attached, and that of a spring 32 clockwise in the drawing is biased, one end of which slides on a cam portion 22 a of the AF control plate 22 and be opposite end firmly a light projection element 33 carries. A projection lens 34, a light condensing lens 35 and a photosensitive element 36 form part of an automatic distance measuring device from the active one Type. Details of the automatic distance measuring device are in Japanese Patent Laid-Open Patent application 55-40438 and should therefore not be explained in detail here. Also a focus control mechanism for an object that responds to the movement of the AF control plate 2 2 is known and should therefore not be explained in detail here.

The mode of operation of the coordination shown in Figures 1 - 5

dination system is intended to refer to the successive ■ Steps for the operation of the camera are explained.

When a shutter release button, not shown, is first depressed, a control circuit described later energizes solenoid 2 with a "pull" current of, for example 200 mA for a certain period of time (for example 10 ms), and the resulting magnetic force causes the yoke 1 attracts the armature 3, so that the bent portion 5 a of the control lever 5, which is integral with the Armature 3 moves out of engagement with a tab 7 a of the drive plate 7 comes. The drive plate 7 moves under the action of the spring 9 to the right. Then an extension 7b of the drive plate 7 rests on one Tabs 5 b on the opposite end of the control lever 5. Therefore, the drive plate 7 is stopped once here. This state is shown in FIG. At this time, a projection 7 c of the drive plate 7 lifts the Extension of the locking lever 19 high, so that the locking lever 19 turns clockwise against the biasing force of the spring

25 is rotated so that it is out of engagement with the AF

Control plate 22 is coming. The AF control plate 22 then begins a movement to the left, as shown in Figure 2, due to the force of the spring 21. As a speed reduction mechanism at the same time consisting of the escape wheel

26 and the armature 28 works, the AF control plate 22 moves at a certain speed. The lever 30, which carries the light projection element, is moved by a cam portion 22 a of the AF control plate 7, whereby a distance measuring process is initiated. If then a signal that the detection, des in-focus is generated by the photosensitive member 36, that described later operates Control circuitry so that it interrupts the "hold" current for the solenoid 2. Since the anchor 3 attracting Force disappears, the control lever 5 is moved counterclockwise by the pretensioning force of the spring 6.

rotates so that the tab 5 b comes out of engagement with the bent portion 7 b of the drive plate 7. Like in the As shown in the figure, the drive plate 7 then moves due to the action of the spring 9 to the right until a second Tab 7 d of the drive plate 7 rests against the bent section 5 a of the control lever 5. The movement of the Drive plate 7 causes its projection 7 c to be moved away from the extension of the locking lever 19, which in turn causes the lock lever 19 by the biasing force the spring 21 is rotated counterclockwise so that it engages in one of the teeth 22 b of the AF control plate 22, whereby the AF control plate 22 is fixed. This state is shown in FIG.

In this connection, it should be stated that if at this point in time the start of a shutter operation is controlled after a certain time from the start of the AF operation by a signal generated by a timer circuit and a signal indicating the termination of the AF operation. Process represents, the following sequence proceeds as follows: Assuming that the AF process takes less time than the time set in the timer circuit, a certain period of time occurs between the release of the control lever 5 from the yoke 1 when the AF process and the initiation of the shutter sequence, since, as explained above, a working cycle begins with the release of the flap 5 b of the control lever 5 by the bent portion 7 b of the drive plate 7, in which a movement to the right of the drive plate 7 due to the Effect of the spring 9 occurs and the engagement between the bent portion 5 a of the control lever 5 and the second tab 7 d of the Ste lower plate. 1 is terminated without hindrance. On the other hand, suppose that the termination of the AF operation occurs close to the termination of the time interval set in the timer circuit, and therefore the time between the moment the power is supplied to the solenoid 2 to release the control lever 5 of

Yoke 1 has been interrupted since the AF operation has been completed until the moment the solenoid 2 is again excited to initiate the locking process, extremely short, so will, as explained above, before the bent portion 5 a of the control lever 5 with the second tab 7 d of the drive plate 7 comes into engagement, current to the solenoid 2 to initiate the closure process and the control lever 5 is again attracted to the yoke 1 so that it rotates clockwise in the figure, which has the consequence that the camera itself on "Shutter sequence" switches regardless of the fact that the point at which the worktop 7 starts is different from differs from the point where it normally lies when the bent portion 5 a is in engagement with the flap 7 d of the drive plate 7 is. Therefore, the speed of movement of the drive plate 7 is changed what a negative influence on the accuracy of the control of an automatic exposure process (hereinafter referred to as an AE process). It is assumed again that the completion of the AF operation is delayed from the completion of the duration of the time interval indicated on the timer circuit is set, and that therefore a current is immediate upon completion of the power supply to the solenoid 2 in response to the signal indicating the completion of the AF operation indicates, flows through the solenoid 2 to actuate the shutter release, it often happens that, during the engagement of the tab 5 b of the control lever 5 with the bent portion 7 b of the drive plate 7 has not yet been released, the circuit in the operating mode for the closure process. Even if in this case the control circuit described later outputs the signal, indicating the completion of the AF operation, the drive plate 7 does not move. Therefore, the lock lever 19 cannot Set the AF control rod 22 longer. Thus, the AF process has no effect. Even when the control circuit has generated an actuation signal for the shutter sequence is no recording possible because the lock is mechanically attached to the

run is prevented.

In connection with this exemplary embodiment, it should be noted that that the length of time between the final energization of the solenoid 2 by the termination of the AF operation the release of the tab 5 b of the control lever 5 before. the bent Section 7 b of the drive plate 7 indicating signal, the movement of the drive plate 7 due to the Biasing force of the spring 9, and the engagement between the bent portion 5 a of the control lever 5 and the Tab 7 d of the drive plate 7 to stop the drive plate with sufficient mechanical stability necessarily is greater than about 10 ms, as has been found experimentally.

The operations following the completion of the AF operation will now be considered. If the Armature 3 is tightened again to the yoke 1, the bent section 5 a of the control lever 5 comes out of engagement with the 2nd tab 7 d of the drive plate and the drive plate 7 begins again to the right in the drawing due to the action of the spring 9 to move. This state is shown in FIG. ·

At this point, there is a hook-shaped portion 10a of the opening lever 10 in engagement with one end 15a of a opening and closing lever 15. As the drive plate 7 moves, therefore, the opening and closing lever rotates 15 clockwise in the drawing. Since furthermore the. On the Opening and closing lever 15 attached pin 16 engages in a longitudinal slot of the shutter curtain 13, rotates the latter turns counterclockwise in the drawing about axis 14, thereby initiating an exposure will. The exposure continues as long as the armature 3 is attracted to the yoke 1. Then light goes from one object to be photographed through the auxiliary aperture 13a through it, so that it is on a later described

Photocell hits. This results in what is known as an auxiliary aperture light measurement executed. Then, when a control circuit described later generates a signal that the termination the exposure indicates / is the power supply interrupted to the solenoid 2, whereby the armature 3 is no longer attracted. Then the control lever 5 rotates in the opposite direction clockwise due to the action of the spring 6, so that its one end 5 c against the opening lever 10 at whose end portion 10b strikes, its opposite End 10a disengaged from end 15a of the opening and Closing lever 1.5 comes. The opening and closing lever 15 rotates counterclockwise due to the biasing force the spring 18, while the locking, Blade 13 rotates in a direction in which the exposure aperture is closed. This is shown in FIG.

It should be noted that the foregoing procedure completes a series of operations from depressing the release button range from actuating the distance setting to opening and closing the shutter. If then when a clamping mechanism, not shown, is operated, the AF control plate 22 and the drive plate reverse 7 return to their original positions.

A control circuit for such a camera will be explained below. The examples according to the figures 6 and 8 differ only in the part by which the power supply for the solenoid 2 is controlled but similar in their structure in the other parts.

First, the example according to FIG. 6 will be explained. In this figure, A is a light measuring circuit; in this Light measuring circuit 38 is an operational amplifier (hereinafter abbreviated as OP amplifier) which is a spc head amplifier forms, 39 is a photovoltaic cell (photocell, also known as spc) that sits between the two Input terminals of the OP amplifier is switched; 40

- 14 - ■

is a compression diode that is located in the feedback of the OP amplifier. A reference voltage VREF, the magnitude of which is proportional to the absolute temperature, is applied to the non-inverting (+) input terminal of the OP amplifier 38. An expansion transistor 41 is connected to the output terminal of the OP amplifier 38, and a timing capacitor 42 is connected to the collector; a count start switch 43 is connected in parallel with capacitor 42 and is adapted to be moved from its normally closed position to the open position when the shutter opens. The positive input terminal of a comparator 45 is connected to the collector of the expansion _{transistor 41, and a reference voltage V T} "of an electrical power source Vcc is applied to the negative input terminal; the comparator 45 produces an output signal AECUP when the time capacitor 42 ends the counting process. 13 a is the auxiliary diaphragm already mentioned. 37 is an ND filter (neutral density filter) which is used to adjust the ASA sensitivity information of the film used.

B is an active type AF circuit in which, as well is known, · Infrared light is used. With this AF circuit two input NAND gates 50 and 51 form an RS flip-flop (hereinafter abbreviated as RS-FF). An input port a NAND gate 52 with three input terminals is connected to the output terminal of the NAND gate 50; A CLOCK signal and an AFEND signal are applied to the other two input connections, as described in more detail below will be described. A switching transistor 53 is connected to the output terminal of the NAND gate 52. Resistances 54 and 55, an OP amplifier 57 and a transistor 58 constitute a constant voltage circuit. The non-inverting one The input connection of the OP amplifier 57 is via a resistor 56 with a temperature-independent reference voltage KVC connected; the inverting input terminal is to the junction of resistors 54 and

55 connected. A light emitting diode 33 for the infrared range (hereinafter abbreviated as iRED) is connected to the emitter of transistor 58. 34 is a projection lens for iRED 33, 59 an object to be photographed, 35 a converging lens, which collects the light reflected from the object, 36 an SPC (photocell) which receives the reflected light. An amplifier 60 amplifies the output of the SPC 36; a peak detection circuit 61 of known Construction detects the peak value of the output signal of the SPC 36; 62 is a circuit that generates a signal that the detection of the armed state indicates (hereinafter abbreviated as AFEND signal). An inverter is connected to the output terminal of the waveform switch 62 connected and generates an AFEND signal. SW2 is a switch which is adapted to be activated by the second hub a release actuation of the camera is closed; the switch SW2 is via a resistor 47 with an electrical Power source connected to Vcc. NAND gates 46 and 48 form an RS-FF. An inverter 69 is connected to the output terminal of the NAND gate 46. At the end of the NAND gate 46 and the inverter 69, an SW2 signal and an SW2 signal, respectively, are output; Reference voltage generating circuits 64 and 65 generate a temperature-independent reference voltage KVC and one of the absolute Temperature-dependent reference voltage VREF.

66 is an electric power source or a battery; SW1 is a switch which is designed to switch through the first stroke of the shutter release of the camera is closed. A resistor 67 and a capacitor 68 are connected to each other connected at a point where inverters 7 and 7 are connected in series so that inverters 69 and

70 generate a PUC signal and a PUC signal.

71 and 72 are NAND gates which form an RS-FF, with an 1OM signal at one input terminal of the NAND gate 71, which will be described later, via an in-

verter 74 is applied and at one input terminal of the NAND gate 72 the SW2 signal. 73 is an AND element, with 2 input connections, at one input connection of which the SW2 signal is applied and at the other input connection that pending at the output connection S11 of the NAND gate 72 Signal is present.

75 and .76 are NAND gates that form an RS-FF, where at one input terminal of the NAND gate 75 a 122M signal, which will be described later, via an In- · verter 78 is applied and at one input terminal of the NAND gate 76 a 112M signal. 77 is an AND element with two input connections to which the output'signa.l S21 of the NAND gate 76 and the 112M signal 'are present. 79 is an OR gate with two input connections to which the output signals S12 and S22 of the AND gates 73 and 77 are present.

84 and 85 are NAND gates which form an RS-FF, with one input terminal of the NAND gate 84 having one NOR gate 83, the AFEND signal and a 96M signal are present and at one input terminal of the NAND gate 85 the SW2 signal.

86 is an AND gate with two input terminals to which the output signal S31 of the NAND gate 85 and the SW2 signal issue.

8, 8 and 89 are NAND gates which form an RS-FF, with the PUC signal at one input terminal of the NAND gate 89 and the 112M signal is applied to one input terminal of the NAND gate via an inverter 87. 91 and are NAND gates which form an RS-FF, v / obei at one input terminal of the NAND gate 91, the AECUP signal and an the one input terminal of the NAND gate 92, the output signal of the NAND gate 89 as an output signal S43 of an inverter 90 are present.

93 is an AND gate with two input terminals, with which the output terminal S41 of the NAND gate 42 and the Output terminal S43 of the inverter 90 are connected. 94 is an OR gate with two input terminals ·, with which the output terminals S32 and S42 of the NAND gates 86 and 93 are connected. Switching transistors 80 and 81 are connected to the output terminals of the OR gates 79 and 94 and control the flow of a "pull" current and a "hold" current through solenoid 2. 82 is a resistor, which limits the "hold" current.

100 is an oscillator circuit, 101 is a frequency divider circuit, which is the frequency of the output pulses of the oscillator circuit 100 divides, with a pulse chain with a frequency of about 10 at its "CLOCK" output connection KHz is pending.

102 to 107 are D-FF that are connected to each other in the manner shown are connected and form a frequency divider circuit. To the "CLEAR" connections (clear connections) of the frequency divider circuit 101 and the D-FF 102 to 107 is the SW2 signal created. An AND gate 108 has two input terminals with which the Q output terminals 2M and 8M of the DFF and 104 are connected. An AND gate 109 has three input terminals with which the Q output terminals 16M, 32M and 64M of the D-FF 105, 106 and 107 are connected. An AND gate 110 has two input connections, with. where the Q output terminals 32 M and 64 M of the D-FF 106 and 107 are connected. The output terminal or the output signal · des AND gate is designated 96M. '· · "

111 is an AND gate to which the output signals 10! YL and 112M of AND gates 108 and -109 are applied and whose output signal is designated 122M.

At this point it should be mentioned that the signal names such as 10M and 112M imply that the signals are on

high level in 10msec or 112msec after the appearance of the SW2 signal can be inverted.

The operation of the circuit shown in FIG. 6 will now be described with reference to the pulse / time diagram can be described in FIG.

When the shutter release button of the camera is depressed to the first stage is closed, the switch SW1 is closed, whereby the capacitor 68 of the resistor 67 flowing current is charged. During the short charging time, the outputs of inverters 69 and 70 go high or low level, so that the PUC signal and the PUC signal are issued.

Due to the PUC signal, the output signal of the NAND gate 51 has a high level, and there is the SW2 signal at this point in time is high, the output of the NAND gate 50 is low. Similarly, take the output signals the NAND gates 48 and 46 to high and low levels, respectively, and the output signals of the NAND gates 89 and 88 high or low level.

The peak value detection circuit 61 and the pulse shaping circuit 6 2 for the focus signal are set to their initial states by the PUC signal. Since the output signal of the NAND gate 46 has a low level in this position (the rest position in which only the switch SW1 is switched on), no SW2 signal and no SW2 signal are yet generated. Since the SW2 signal is low and the SW2 signal remains high, the Di ¹ F 102 to 107 are cleared by the SW2 signal so that their Q outputs are low. Therefore, the output signals of the AND gates 108 to 111 have a low level. At this time, therefore, an input terminal of the AND gates 73, 77, 86 and 93 is applied with a low level signal so that their output signals

and the outputs of OR gates 79 and 94 are low Stay level and the switching transistors 80 and 81 block. Thus, the solenoid 2 becomes the driving magnet not powered. Since in this position the SW2 signal, the 112M signal and the output signal S43 of the inverter 90 are low, the NAND gates 72, 76, 85 and 92 are set so that they output signals S11, Generate S21, S31 and S41 of high level.

Since if the release button is pressed further down on the second stage the switch SW2 is closed, .will an input signal of the NAND gate 4 6 is inverted to a low level, so that an output signal assumes a high level, thereby generating the SW2 signal. The output signal of the inverter 49 also changes at this point in time low level, generating the SW2 signal.

Therefore, the output signals S12 and S32 changed AND gates 73 and 86, which respond to a high level output signal S11 of the NAND gate 72 and a high level output signal S31 of the NAND gate 85 respond to high Level. With this, the output signals of the OR gates 79 and 84 change to a high level, whereby the drive transistors 80 and 81 are switched through. Thus, the power supply for the solenoid 2 becomes the driving magnet initiated. This leads to the initiation of the AF process described above, since the armature is attracted to the yoke 1 is so that the bent portion 5 a of the control lever 5 out of engagement with the tab 7 a of the drive plate 7 is coming.

This change in the SW2 signal low causes that the D-FF 102-107 are released from the deleted state. This continues the further lowering of the frequency of the output pulses of the frequency dividing circuit 101 through the D-FF 102 to 107. More precisely, they change Q output signals 2M to 64M of the D-FF 102 to 107 in 2msec,

4msec, 8msec, 16msec, 32msec and 64msec, from the appearance of the SW2 ~ signal at high level. The output signals also change 10M, 112M, 96M and 122M of the AND gates 108 to 111 in 10msec, 112msec, 96msec and 122msec on high Level (see Figure 7).

Since the AND gate 108 generates a 10M signal when the The output of the inverter 74 changes to a low level, the output of the NAND gate 71 changes to a high level Level and the output signal S11 of the NAND gate 72 low level. Therefore, the output signal S12 of the AND gate 73 changes to the low level, so that the transistor 70 blocks, whereby the supply of a "pull" current for the solenoid 2 of the drive magnet ceases. Short said the solenoid 2 is supplied with a "pull" current for 10 msec depending on the signal S 12 (see FIG. 7). It should be noted that the signal S32, which controls the supply of the solenoid 2 with a "hold" current, also after this time is still present, as FIG. 7 shows, so that the armature 3 is kept attracted by the yoke 1.

On the other hand, by the time the SW2 signal changes is generated, the output of the NAND gate is high. Since at this point the AFEND signal does not appear, the NAND gate 52 generates an output signal which is in the form of an inverted CLOCK signal (clock signal) Has. In response to this signal, the switching transistor 53 is switched through or the switching transistor blocks. Therefore, a constant voltage is applied to the light projection element (iRED) 33, which is determined by the reference voltage KVC and the ratio of resistors 54 and 55 is determined in synchronism with the CLOCK signal. Thus the lights up iRED 33 on. This means that closing the switch SW2 causes a first power supply to the solenoid 2, whereby in turn, the start of the movement of the AF control plate 22 is caused. When the AF control plate 2'2 moves, scans the light emitted by the excited iRED 33 the field of view. The light reflected from object 59

enters the photosensitive member 36. The output signal of the photosensitive element 36 is amplified by the amplifier 60. The amplified signal will then synchronously with the CLOCK signal in the next stage ■ the peak value detection circuit 61 is measured; at the time when a peak value of the synchronously measured Output signal is outputted, the output signal assumes a high level. After a certain period of time after the Generation of the peak value signal generates the waveform shaping circuit 62 for the focus signal in the next Stage an AFEND signal. The generation of the APEND signal causes the output of NOR gate 83 to change to a low level. Therefore the output signal changes of the NAND gate 84 at a high level and the output signal S31 of the NAND gate 85 at a low level (see Figure 7, S31). So that's changing at this point Output signal S32 of AND gate 86 at a low level, so that drive transistor 81 blocks and the supply of the solenoid 2 is terminated with the "hold" current. The solution described above for the anchor 3 of FIG the attraction of the yoke 1 takes place and the arrangement described above acts with the AF control plate 22 in this way together that the toothed portion 22 b comes into engagement with the locking lever 19 and the lens to another Axial movement is prevented; the distance setting process is thus ended.

Since this is followed by the counting process of the D-FF 102 bis continues, the output signal 112M of the AND gate 109 changes to high level when all of the Q outputs of the D-FF 105,106 and 107 go high. Because about this Time the output signal S21 of the NAND gate 76 is set to a high level, the output signal S22 takes the AND gate 77 high level; the output of the OR gate 7 9 also assumes a high level, - so that the drive transistor 70 is switched through. Therefore there is a second supply of the solenoid 2 with a "pull" -

Current instead, so that the armature 3 attracts the yoke 1 again. As described above, an opening operation of the shutter is initiated. After 10 msec from the supply of "pull" current, the output signal 122M of the AND gate 111 changes to a high level (see FIG. 7, 122M), so that at this point in time the output signal of the inverter 78 changes to a low level and that Output signal of NAND gate -75 at high level. Therefore, the output signals S21 and S22 of the NAND gate 76 and the AND gate 77 change to a low level, so that the drive transistor (driver transistor) 80 blocks, whereby the supply of "pull" current is terminated. On the other hand, since the output of the inverter 87 changes to the low level when the output 112M of the AND gate 109 becomes high, the outputs of the NAND gates 88 and 89 are set to high and low levels, respectively. Therefore, the output signal S43 of the inverter 90 is inverted to a high level, thereby causing the output signal of the AND gate 93 and the output signal S42 of the OR gate 94 to change to a high level. Therefore, the drive transistor 81 is turned on when the output signal 112M of the AND gate .109 assumes a high level. It should be noted that even after the "pull" current is interrupted, the "hold" current continues to flow through the solenoid 2 "(see Fig. 7, S42, S43). On the other hand, in the above-described embodiment, the Auxiliary opening 13a, when the shutter-opening operation progresses, opens again after it has closed once, the output signal of the operational amplifier 38 changes logarithmically depending on the amount of light incident on the SPC 39 and a current proportional to the amount of incident light flows to the Collector of the expansion transistor 41; this current stores the time capacitor 42. When the voltage on the capacitor 4 2 reaches the threshold voltage V _TH , the output signal AECUP of the comparator 45 is inverted to a low level.

the 91 and 92 are set to produce high and low level outputs, respectively. Then that changes Output signal S42 of AND gate 93 at a low level; the output of the OR gate 94 also changes to a low level, whereby the driver transistor 71. locks. That is why at this point the supply of the solenoid 2 with "hold" current interrupted and, as described above, the armature 3 released, so that the opening lever 10. Out of engagement with the opening and closing lever 15 comes, whereby the closing process of the shutter is initiated.

It should be noted that in this embodiment the 96M signal of AND gate 110 and AFEND signal through the ■ NOR gate 83 are combined so that even if the ÄFEND signal does not appear, the output of the NOR gate 83 changes to low level 96msec after the generation of the SW2 signal, so that the "hold" current for the automatic focus is interrupted without the AF operation not stopping. In this case too starts 112msec after the generation of the SW2 signal "Pull" current to flow for the shutter actuation. In other words, in this embodiment it is the interval time selected between the termination of the AF process and the initiation of the shutter cycle as about 16 msec (If the inertia of the mechanism is taken into account, it can be shorter), so that even in the worst case the the disadvantages of the other coordination mechanisms described above can be avoided.

In the following a further exemplary embodiment will be described with reference to FIG. 8, in which the same Reference symbols for designating parts similar to those in FIG 6 can be used.

78 'is a NAND gate to which an AFEND signal and a 26M signal, which will be described later, are applied

and the output of which is applied to one input terminal of a NAND gate 75 which forms part of an RS-FF. The output signal S43 of the inverter 90 is applied to each input terminal of the NAND gate 76 and the AND gate 77. The NAND gate 84 forms part of an RS-FF, at one input terminal of which the AFEND signal is applied via an inverter 83 '. 87 'is a NAND gate to which the AFEND signal and a 16M signal are present and the output signal of which is applied to one input terminal of the NAND gate 88 which forms part of an RS-FF. 122 is an AND gate with 2 input terminals to which the output signal 1OM of the AND gate 108 and the Q output signal 16M of the D-FF 105 are present. 121 is a monostable pulse shaper circuit to which the AFEND signal is applied. Its output signal ONSHT and the SW2 signal are applied to an OR gate 120 with two input connections, the output connection of which is connected to the clear connections of the frequency divider circuit 101 and the D- FF 102 to 105 is connected.

The mode of operation of the circuit according to FIG. 8 is described below with reference to the pulse / time diagram in FIG 9 will be described.

The sequence from pressing the second stroke of the release button to generating the AFEND signal is the same as in the first embodiment; therefore is on a Description omitted. When the AFEND signal is generated, the output of the inverter 83 'goes low on, thereby causing the output signal S32 of the AND gate 86 to change to a low level, whereby the Driver transistor 81 blocks, so that the "hold" current for the AF process control is interrupted. Therefore will by the mechanism described above, a further axial movement of the lens is stopped and generated at the same time the one-shot pulse shaping circuit 121 generates a pulse (see FIG. 9, ONSHT). One impulse goes through that

OR gate 120 for one-time resetting of the D-FF 102 to 105 and the frequency divider circuit 101. Then start the D-FF 102 to 105 restart the counting process from their initial state. As their counting progresses, the two take Input signals of the NAND gate 8-7 '. Simultaneously high Level on when the Q output 16M of the D-FE-105 is high is inverted, and the output of the NAND gate changes to the low level. That is why the NAND terms 88 and 89 are set to produce high and low level outputs; the output signal S43 of the inverter 90 is inverted to a high level (see FIG. 9, S43). On the other hand, since the output signal S41 of the NAND gate 92 is first set to a high level, causes the output signal S43 to change to a high level, that the output signal S42 of the AND gate 93 changes to a high level. '

Since the output signal S21 of the NAND gate 76 is also first is set to the high level, causes the inversion of the Output signal S43 of the inverter 90 at a high level that the output signal S22 of the AND gate 77 is at a high level changes (see Figure 9, S22).

Thus, the driver transistors 80 and 8-1 are turned on, so that the solenoid 2 with "pull" current and "hold" current is supplied to the closure sequence control and the opening process of the closure begins. Because the counting process of the frequency dividing circuits 102 to 105 advances, the output signal 26m of the AND gate changes 122 at a high level when two high-level input signals are present at the AND gate 122. That's why they both take Input signals of the NAND gate 78 'goes high at a point in time, and its output signal changes to low Level. Then the NAND gates 75 and 76 are reset to have high and low output signals, respectively Generate level. Then the output signal S22 of the AND gate 77 changes to a low level, whereby the driver

transistor 80. blocks, so that the supply of the solenoid 2 with "pull" current is interrupted.

Since the opening process of the shutter according to the Closure sequence continues as in connection with In the first embodiment, the outputs of the NAND gates 91 and 92 go high or low level, and the output signal S42 of the AND gate 93 low level when the output signal AECÜP the comparator circuit 17 is inverted to a low level. Therefore blocks the driver transistor 81, so that the Supply of the solenoid 2 with "hold" current is interrupted. Then the mechanism described above works the closure into the closing process.

This means that in this embodiment the supply of the shutter with "pull" current 16msec after the appearance of the AFEND signal begins and a device, which sets a waiting time for the AFEND signal - as in the first exemplary embodiment - is not provided. That's why follows in the circuit according to FIG. 8 16 msec after termination of the AF operation is the start of the shutter operation, with the advantage that the time from the operation of the camera's shutter release can be shortened to the start of the exposure process, allowing the photographer did not miss the lock change. However, this embodiment has the disadvantage that the time difference at the beginning of the shutter sequence differs for small and large object distances. on the other hand In the embodiment according to FIG. 6, it is more advantageous that the time difference at the beginning of the closure sequence can be kept almost constant.

As described above, according to the present invention created a camera in which an electromagnetic device timed the AF process and the shutter sequence controls successively, with after the lapse of min-

at least a predetermined time after the completion of the AF operation, the power supply to execute the shutter operation takes place for the electromagnetic device, so that it becomes possible incorrect operations of the armature or the like, the operation of which is controlled by the electromagnetic device, and extremely stringent requirements for the accuracy and reliability of controlling the operation of the camera to meet. · ·. ■

It goes without saying that the present invention has and has not been described above by way of example on the system described above and its numerical see data is limited. Of course, they are very diverse Modifications are possible without departing from the general inventive concept.

A camera with an automatic focusing device is described and an automatic exposure control device, which in time successive Manner coordinated by a control device having only one electromagnetic device; the operation of the automatic focuser is powered by the electromagnetic Device controlled during a first period of time, and the operation of the automatic exposure control device is controlled by the power supply to the electromagnetic device for a second period of time, wherein the termination of the power supply during the first period of time at least after a certain time delay the start of the power supply of the second period follows.

L e r s e i t e

Claims (5)

PATENT CLAIMS 1. Camera with an automatic distance setting device and an automatic exposure control device characterized in that it is an electromagnetic Device (1,2) which is an automatic distance setting device during a first period of time and an automatic exposure control device actuated during a second period of time, a first Power supply circuit (71, 72, 73, 74, 83, 83 ', 84, 85, 86) which provides the power supply for the electromagnetic Controls device during the first period, and a second power supply circuit (75, 76, 77, 78, 78 ', 87, 87', 88, 89, 90, 91, 92, 93) which the Controls power supply of the electromagnetic device during the second period of time, wherein the second power supply device the power supply control after at least a predetermined time has elapsed the completion of power supply control by the first power supply circuit begins. Deutsche BanK (Munich, KIo 51/61070 Dresdner Bank (Munich) KIo 3939844 Postal check (Munich) KIu 670-43-804 2. Camera according to claim 1, characterized in that a timer device (100 to 107, 109, 110) is provided which generates a first signal followed by a second signal after a certain time, where the first power supply circuit responsive to the power supply of the electromagnetic device (1, 2) either the focus signal of the automatic focuser or the first signal ends / and the second power supply circuit the power supply of the electromagnetic device (T, 2) begins in response to the second signal. 3. Camera according to claim 1, characterized in that the Power supply of the electromagnetic device (1, 2) from the first power supply circuit through the Focus signal from the automatic focuser is stopped, and the power supply of the electromagnetic device (1, 2) through the second power supply circuit is started by the signal given by the timer means (100 to 105) after the elapse a certain time from the occurrence of the focus signal. 4. Camera according to claim 2 or 3, characterized in that the first power supply circuit is the power supply for the electromagnetic device in response to the actuation of a camera trigger begins / and that the second Power supply circuit provides power to the electromagnetic device in response to an exposure complete signal of the automatic exposure control device ended. 5. Camera according to claim 4, characterized in that the electromagnetic device is an electromagnet which is designed so that it attracts an armature when the power supply starts and when the power supply is terminated loosens the anchor.