DE3921643C2 - Electronically controlled camera with electronic calculation of recording parameters - Google Patents

Description

The invention relates to an electronically controlled camera electronic calculation of recording parameters according to the preamble of claim 1.

Such cameras usually have a distance measuring unit and one Display unit that lights up or flashes and thus signals the completion of the distance measurement.

Cameras with built-in distance and light measurement units have so far been largely as a single image cameras, especially as cameras with central locking, realized.

A camera of this type with automatic focus position measures the distance to the object with the Distance measuring unit, sets the lens accordingly the measured distance and determines the closure time depending on the sanctity of the object with the light measuring unit is measured.  

Such a camera is in JP 62-58 233 A. described. With this camera, the Focusing with a light emitting diode shows. Another LED flashes when the Camera is in self-timer mode.  

The problem with a camera of this type is that them to check the normal functioning of the determination of recording parameters must be disassembled to elek uncover trical connections, which then with measuring instru elements are to be connected in order to avoid the Check signals.

The object of the invention is an electronically controlled camera specify where the admission parameters are without disassembling have the camera checked.

The task is solved by an electronically controlled camera with the Features of claim 1.

Further features and advantageous developments of the invention are Subject of the subclaims.

The camera can do one Distance measuring unit for measuring the object distance, a light measuring unit for measuring the object brightness and have a display unit showing the distance measurement signals. There is a flashing control unit to flash the display unit accordingly Provided photometric data that the Lichtmeß unit when the display unit is actuated.  

With a Monitoring unit for monitoring the functioning of a Measuring unit can be information about get a predetermined parameter. The Measuring unit provides an indication of the measured informa tion, for example with an indicator lamp. The Measuring unit contains an arrangement for blocking the on show for a predetermined time after a Time interval that get on that with the measuring unit related information. The surveillance direction measures the length of the time interval and delivers a corresponding display, preferably in the form of monitored parameters for confirmation. The invention is particularly suitable for monitoring a distance voltage measuring unit or a light measuring unit in one automatic camera so that the correct operation of these units checked without disassembling the camera can be.

The indicator lamp on the electronically controlled camera can light up be interrupted for a predetermined time which is the end of the time interval. This Interruption can occur through the human eye are not perceived and is about 250 µs.  

To ensure that decoding with the tester does not provide a falsified result, becomes the operation of the surveillance unit for a predetermined time, preferably for approx. 300 ms, delayed before the length of the time interval valls is measured.

The length of the time interval can be determined with a photo cell measure on which the light of the indicator lamp falls.  

The invention is described below with reference to the drawing explained in more detail. In detail show:

Fig. 1 is a front view of an execution example of the camera according to the invention,

Fig. 2 is a plan view of the camera,

Fig. 3 is a rear view of the camera,

Fig. 4 is a block diagram showing the major parts of the control system of the camera,

Fig. 5 to Fig. 7 are flow charts for the control system of the camera,

Fig. 8 is a flowchart for the output of Entfernungsmeßstufenwerten, which are used in connection with the monitoring unit,

Fig. 9 is a representation of the luminous state of a green indicator light,

Fig. 10 is a block diagram of a measuring device of the camera,

Fig. 11 is a flowchart for the measuring device according to Fig. 10,

Fig. 12 and 14 are flowcharts for other parts of the camera Fig. And

Fig. 13 is an illustration of a further illuminating state of the indication lamp.

In Figs. 1 to 3, a compact camera with lens and shutter shown Autoblitz, in its housing 25, the lens 20 and the viewfinder system 21 independently of one another are installed. Fig. 1 shows the front view of the camera, while Fig. 2 shows the top view and Fig. 3 shows the rear view. A flash unit 22 , a photocell 23 for light measurement, an infrared light-emitting diode (IRED) 56 and a position sensor (PSD) 57 for emitting a position signal corresponding to the object distance by reflected infrared light are provided on the front of the camera housing 25 .

A fixed lens barrel 26 is arranged on the camera housing 25 . A movable lens barrel 27 for the lens 20 is arranged in the fixed lens barrel 26 and can be moved out of it if necessary. The movable lens barrel 27 changes its position between a rest position, which is shown in dash-dotted lines in FIG. 2, and an extended NEN operating position, which is shown in dashed lines in FIG. 2 Darge. The focal length of the objective 20 can thus be changed between 38 mm and 60 mm. If the movable lens barrel 27 is held in the dot-dash position shown, the lens 20 is provided with a cover, which is not shown in FIG. 2.

There is a triangular operating button arrangement 28 on the camera housing 25 , which also serves to control the zoom lens. The front part forms a button 28 a, which contains a two-stage switch, namely a light measuring switch and a release switch, the actuation of which will be explained and is shown in the flow diagrams. On one side of the rear part of the operating button arrangement 28 there is a button 28 b which actuates a tele switch. On the other side is a button 28 c that operates a wide-angle switch. These three buttons 28 a, 28 b and 28 c can be operated independently of each other. If one of them is pressed, the other two cannot be operated.

On the back of the camera housing 25 above the cover 29 are provided: a main switch 30 , a mode switch 31 with which it is possible to switch to daylight synchronous operation, a liquid crystal display 32 (hereinafter referred to as LCD display) for displaying the number recorded images (ie the number of exposed image fields that were transported in the camera), the focal length of the objective 20 and other information, a light emitting diode RD that emits red light (hereinafter referred to as a red light display) and a light emitting diode GD that emits green light (hereinafter referred to as green light display). On the inside of the rear wall 29 are the following, shown in dashed lines in Fig. 3 scarf: a film switch 33 , which detects the presence of a film in the film chamber, and a film transport switch 34 , which emits transport pulses corresponding to the transport movement of the film. The main switch 30 is a slide switch with three positions, a blocking position, an on position and a macro position.

The red light indicator RD flashes when the flash unit is not ready to flash and the light measuring switch is in the ON position. The red light indicator RD lights continuously when the flash unit 22 is ready to flash and the button 28 a is pressed. The green light indicator GD flashes when the object is too close when the light measuring switch is in the ON state. It lights up continuously when the object is in the correct distance range for shooting.

Fig. 4 is a block diagram of the major functional units of the control system showing the camera. There are the light measuring switch 51 and the trigger switch 52 , which are actuated by pressing the button 28 a. A power supply circuit 53 includes a battery, not shown. A flash control unit 54 fires the flash unit 22 and includes a high voltage circuit and a capacitor which is charged thereby. The energy stored in it is passed to the flash unit 22 so that it detects.

A light measuring unit 55 measures the brightness of the object on the basis of the signals from the photocell 23 , which is acted upon by the object light. The distance measuring unit 58 calculates the distance to the object accordingly, position signals which are generated with the light-emitting diode (IRED) 56 and the position sensor (PSD) 57 after reflection on the object. A shutter block 59 is controlled by a shutter controller 64 . The shutter block 59 creates an object image on the film by moving a focus lens, not shown, with a built-in stepper motor. This locking block 59 is, for. B. from Japanese Offenle supply document 65-225122 known.

A lens motor 61 moves the lens barrel 27 backwards and forwards. A motor controller 63 controls the lens motor 61 when the tele switch 28 b or the wide angle switch 28 c is in the ON state.

The control unit 65 controls the shutter block 59 , the flash control unit 54 , the LCD display 32 and the red light display RD and the green light display GD accordingly data that it from the distance measuring unit 58 , the light measuring unit 55 and the keys 28 b, 28 c and the Switches 30 , 51 and 52 receives.

The operation of the camera is explained below with reference to the flow diagrams according to FIGS . 5 to 8.

When the main switch 30 is moved from the locked position to the ON position or to the MACRO position, the control is brought from the lock routine, not shown, into the main flow shown in FIG. 5. At this point in time, one load flag FCHG ST is set to 1, while two further load flags FCHG RQ and FCHG DSP are set to 0. In step S1, the input states of the switches 28 b, 28 c, rated 51 and 52 and the main switch 30 and stored in step S2. At step S3, the states of the switches 28 b, 28 c, rated 51 and 52 and the shaving coupler 30 again. At step S6, the program branches to the Variofluß (not shown in detail) for controlling the zoom lens from when the main switch 30 and the zoom lens (or the movable lens barrel 27) have different positions or if the telephoto switch 28 b or the wide-angle switch 28 c are in the ON state.

Since the main switch 30 has just been set to ON, the vario control is transferred to bring the movable lens barrel 27 from the position shown in broken lines in FIG. 2 to the position shown in solid lines. After the vario control is carried out in the vario flow, the process returns to the main flow and step S6 is carried out again. At this time, if the positions of the main switch and the zoom lens (or the movable lens barrel 27 ) correspond to each other, control goes to step S7.

At step S7, the stored state of the light measuring switch 51 is compared with the input state of the light measuring switch 51 read at step S3. If no change in these conditions is found, control transfers to step S8. In step S8 it is checked whether the loading flag FCHG ST has the state 1 . This state is set when control passes to the main flow.

Therefore, the process proceeds from step S8 to step S12 to check whether the capacitor of the flash unit has been charged. Control then goes to step S13 to determine whether the capacitor is being charged. If this is not the case, control goes to step S14 to initiate charging and a charging timer is started (step S14, step S15). In step S10, it is checked whether the load flag FCHG DSP is set to 1. If so, the red light flashes at step S23 and control transfers to step S11. If control transfers to the main flow because the load flag FCHG DSP was set to 0, it transfers from step S10 to step S11. At step S11, the program is interrupted for 125 ms. If there are no changes in the states of the switches 28 b, 28 c, determine 51 and 52, so the flash unit in the loop of steps S3 to S8, S12, S13, S17, S10, S11 and S3 charged.

When the flash unit capacitor is on for 15 seconds has been charged, control goes from step S17 at step S18 to end the charging process. If the flash unit has finished charging control from step S12 to step S18, the Charging is interrupted and the red light indicator RD is brought to the OFF state at step S18, after which control transfers to step S19. At In step S19, the loading flags FCHG ST, FCHG RQ and FCHG DSP set to 0 in each case. After charging becomes the routine from step S3 to step S11 executed repeatedly.

In this state, the release button 28 a is pressed and the light measuring switch 51 is brought into the ON state, where it is determined in step S7 whether there is a change in position of the light measuring switch 51 , and control goes from step S7 to step S20. At step S20, it is checked whether the light measuring switch 51 is in the ON state. If this is not the case, the program goes back to step S8. If it is in the ON state, the red light display RD is switched off in step S21, the charging of the flash unit is interrupted in step S22 and the routine AEAF shown in FIG. 6 is transferred.

At step S30 of this routine, distance measurement data Dv, light measurement data Bv and film sensitivity data or ISO data Sv are input. At step S31, the exposure value Ev is calculated by adding the light measurement data Bv and the ISO data Sv. The aperture value Av, which is calculated by the flash control unit, is determined from the distance measurement data Dv and the ISO data Sv. If the flash is required, the flag F FLASH is set to 1. If it is not necessary, it is set to 0. If the object distance is too small to take a picture, the flag F BLOCK is set to 1. If the object distance is correct for a picture, it is set to 0. Thereafter, control proceeds to step S32, in which the distance measurement data is output to turn on the green light indicator GD. The details are shown in FIG. 8 and FIG. 12 with the aid of flow charts. They are described below:
At step S33, a check is made to see if the flag F BLOCK is set to 1 to determine whether the object distance enables recording. If so, control transfers to step S34. This step checks whether the F FLASH flag is set to 1 to determine if a flash is required. If this is not the case, control transfers from step S34 to the trigger routine according to FIG. 7. If a flash requirement is determined in step S34, control transfers to step S35 to check whether the charging process has been completed, ie whether the flash unit is ready for flash. If this is the case, control transfers from step S34 to the trigger routine after the red light display RD has been switched on at step S36. This indicates that the flash unit will fire when triggered. If the flash unit is not ready to fire, the answer is NO in step S35 and control transfers to S37. Here the red light indicator RD is switched off and the loading flag FCHG RQ is set to 1. The control then goes to the charging routine for charging the flash capacitor.

If the object distance is found to be too small to be taken at step S33, control proceeds to step S38. At step S38, the green light indicator GD is flashed, and at step S39 it is checked whether the light measuring switch 51 is in the ON state. If so, the program proceeds to step S40 to check whether the main switch 30 is in the LOCK position. Usually he is not in this position. In step S40, the answer is NO and the program returns to step S38. If the object is too close as long as the release button 28 a is pressed, the release is blocked because the routine with steps S38, S39 and S40 is repeated. At this point, the green light indicator GD flashes at about 4 Hz to indicate that the object is too close. If it is determined in step S39 that the light measuring switch 51 is in the OFF state or if it is determined in step S40 that the main switch 30 is in the LOCK state, the green light indicator GD is turned off in step S41 and the program returns to the main flow.

If control of step S34 or S36 in the flow AEAF shown in FIG. 6 transfers to the trigger routine of FIG. 7, it is checked in step S70 whether the trigger switch 52 is ON. If this is not the case, the program proceeds to step S71 to check whether the light measuring switch 51 is in the ON state. If this is not the case, the green light display and the red light display are switched off at step S73, and control returns to the main flow. If the light measuring switch 51 is in the ON state, the program proceeds to step S72. At step S72, it is checked whether the main switch 30 is in the LOCK position. If this is not the case, the program proceeds to step S70.

If the main switch 30 is not in the LOCK position and the light measuring switch 51 is in the ON position, the program loops with steps S70 and S72 to wait until the trigger switch 52 is in the ON state.

In this state, the user is informed that the green light indicator GD is continuously lit that the object distance is correct. If the trigger switch 52 is brought into the ON state, the program proceeds from step S70 to step S75. The red light indicator RD and the green light indicator GD are turned off in step S75, and the shutter unit is operated to be released in step S76.

At step S77, it is checked whether the flash unit 22 is ready to flash. If so, control transfers to step S78 to set the charging flag FCHG RQ to 1 and the charging flag FCHG DSP to 0 and to charge the flash capacitor for the next shot. Since this charging is not requested for an intended recording, the charging flag FCHG DSP is set to 0 and the red light indicator RD does not light up. Then control transfers to step S79. If the flash unit 22 is not fired, the control automatically proceeds to step S79.

At step S79, it is checked whether a film is in the camera is inserted. If this is the case, the control system closes Step S80. At step S80, the film feed executed, and control returns to the main flow return If the film is not inserted, the tax returns directly from step S79 back to the main flow.

The flow chart shown in Fig. 8 relates to the output of the distance measurement data with the green light display GD. At step S91, the distance level value obtained from the distance measurement at step S30 of the routine AEAF shown in FIG. 6 is set in a counter A. The distance level value corresponds to the distance between the camera and the object. B. can be represented by a number in the range of 1 to 36. The green light indicator GD lights up in step S92 and the program proceeds to step S94 after being interrupted for 250 microseconds or another suitable time interval which is not perceptible to the human eye and is generated in step S93. In step S94, the value 1 is subtracted from the state of the counter A, and in step S95 it is checked whether the counter state is 0. If this is not the case, control returns to step S93.

The flow from step S93 to step S95 becomes again catches up until the counter reading becomes 0. Then the tax goes  tion to step S96, the green light indicator GD turns off is switched and control goes to step S97. The Control then goes to step S98 after going on Step S97 was interrupted for 250 microseconds. At step S98 the green light indicator GD lights up and the control tion returns to the AEAF routine.

As shown in FIG. 9, with this output signal of the distance measuring step, the green light indicator GD, which is switched on in step S92, is interrupted for 250 μs in step S97. Is the distance level value after the distance measurement by the distance measuring unit of the camera z. B. = 10, which corresponded to a certain object distance from the camera, the green light display is switched off at t1 for 250 microseconds after the time T = 250 microseconds × 10, starting with switching on at t1, has expired. Since the switched off state only lasts 250 µs, the user cannot recognize this. However, this pause can be evaluated with a measuring instrument. If the time T between t1 and t2 is detected with a measuring instrument, the distance step can be monitored in accordance with the distance measured value measured with the distance measuring unit 58 .

Fig. 10 shows a block diagram in which the structure is shown of such a measuring instrument for measuring the time T schematically. A photocell 81 emits a signal when it receives the light from the green light indicator GD of the camera. An amplifier 82 amplifies this signal. A computing unit 83 calculates the time T from the received and amplified signals and calculates the distance level from this time T. An indicator 84 shows the value of the distance level. Furthermore, an oscillator 85 and a reset circuit 86 are provided.

In the following, the operation of the measuring instrument shown in FIG. 10 will be explained with the flowchart shown in FIG. 11.

First, the photocell 81 of the measuring instrument is set so that it receives the light from the green light display GD of the camera. Then the current source of the measuring instrument, not shown in the flow diagram, is switched on. Then a 300 ms timer is started at step S100. In step 101 it is checked whether the green light indicator GD is switched off. Since the shutter button 28 a is not pressed, the green light indicator GD does not light, so that the program goes to step S102. This step checks whether the 300 ms timer (counter) has completed its cycle. If this is not the case, the program returns to step 101. Since the shutter button 28 a has not yet been pressed, the green light indicator GD is switched off after 300 ms, and control passes to step S103.

At step S103, it is checked whether the green light indicator GD is turned on. If this is not the case, control proceeds to step S103 returns to the two-stage switch of the shutter button 28 is pressed a, whereby the photometric switch 51 actuated. If the shutter button 28 a is pressed to perform the distance measurement and the green light indicator GD is turned on, the control proceeds to step S104. At step S104, the timer is started and control proceeds to step S105. At step S105, it is checked whether the green light indicator GD is turned off. If this is not the case, control returns to step S105 until the green light indicator GD is turned off.

If the green light indicator GD is turned off, control transfers to step S106 where the timer is stopped, followed by step S107. In this step the distance level value is calculated from the value reached by the timer or counter. The distance level value is displayed with the indicator 84 at step S108, and the program returns to step S100.

Therefore, the distance level value is used to monitor whether the distance measuring unit 58 is operating correctly in the representation of the object distance, so that it is not necessary to disassemble the camera for this. This is particularly advantageous during production, since after the camera has been assembled, the distance measuring unit can be checked quickly and effectively.

If the object distance is too small, the green light indicator GD, as shown in FIG. 9, flashes at a frequency of approx. 4 Hz after it has been switched off for 250 microseconds. This corresponds to an alarm. Incorrect actuation of this alarm can be avoided by setting the measuring unit in the routine of FIG. 11 from step S100 to step S102 so that the measurement is started after it has been confirmed that the green light indicator was switched off for 300 ms.

Fig. 12 shows a flow chart with examples of other operations. It is shown how the distance step values are output as digital signals. First, the lighting period T 'of the green light display GD, which is 8 ms, is divided into 8 intervals of 1 ms each, which are denoted by 0 to 7. The green light indicator GD is operated from 0 to 5 to output the distance level value.

At step S201 in the flowchart shown in FIG. 12, the distance level value is set in counter A, and in step 202, bit 7 of counter A is set to 0 and bit 6 of counter A is set to 1. Since the distance level consists of the 6 bits 0 to 5, these values are not changed. At step S203, 8 is set in the counter B. Then, at step S204, the date in bit 7 of counter A is read out, and the data of counter A is shifted one bit to the left. At step S205, it is checked whether the read data is 1. If this is the case, the green light display GD is switched off in step S207. If the date is 0, the green light indicator GD is turned on at step S206. The program is interrupted for one millisecond in step S208, and the value 1 is subtracted from the value 8 of the counter B in step S209. In step S210 it is then checked whether the level of counter B is 0. If this is not the case, control returns to step S204 to read bit 7 of counter A at step S204 and to shift the data of counter A one bit to the left. In this way, one bit is read from counter A, in a sequence starting from bit 7.

The counter B becomes 0 in step S210 is determined, the process proceeds to step S211, where the green light indicator GD is switched on. Then it will be the program returned.  

The flowchart in Fig. 14 shows reading the digital signal output in the above-described flow. At step S301, the value 6 is set in a counter C, and each bit of a counter D is set to 0. The 300 ms timer starts at step S302, and it is checked at step S303 whether the green light indicator GD is on. In step S304, it is checked whether the 300 ms timer has expired. Since the flow from step S302 to step S304 is the same as that from step S100 to step S102 in FIG. 11, further explanation is unnecessary here.

At step S305, it is checked whether bit 7 of the light signal shown in Fig. 13 is set. At step S306, it is checked whether bit 6 of the light signal is OFF. The process is interrupted for 1.5 ms at step S307, and it is checked at step S308 whether bits 5 to 0 of the light signal are set. If this is the case, the counter A is set to 0 in step S310. If the bits are not set, the counter A is set to 1 in step S309. The data in counters A and D are logically added in step S311, and the result is set in counter A. In step S312, the data of counter A is shifted one bit to the left and is entered in counter D in step S313. At step S314, the value 1 is subtracted from the level of the counter C, and at step S315 it is checked whether the level of the counter C is equal to 0. If this is not the case, the process in step S316 is interrupted for one millisecond, and control returns to step S308. In this way, the data of bits 5 through 0 of the light signal are read in the loop with steps S308 through S316.

If the state of the counter C is found to be 0 in step S315, control transfers to step S317. In step S317, the data in the counter D are shifted to the right by one bit and recognized as a distance level value in step S318, which is represented by the indicator 84 . Then the control returns to the start.

As described above, the invention enables monitoring the distance and the distance Light measuring unit delivered data without disassembling the Ka mera.

The foregoing description relates particularly to that Distance level values. The invention is not based on this limited, it can in the same way also on the Output of photometric data can be applied.

Claims (8)

1. Electronically controlled camera with electronic calculation of recording parameters, in which an operating state is indicated by a perceptible light signal for the user of a light source (GD), characterized in that the light signal emitting light source (GD) by means of a control unit in a pulsed manner is controlled with a respectively predetermined pulse or pause length in order to encode the light signal as a function of a recording parameter, and that the light signal of an external decoding test device can be supplied via a photoelectric converter ( 81 ) thereof. 2. Camera according to claim 1, characterized in that the Switch on state of the light source (GD) by one for the User imperceptible pulse at a time is interrupted, which proportions the recording parameter tional duty cycle ended. 3. Camera according to claim 2, characterized records that the pulse has a length of 250 microseconds. 4. Camera according to one of the preceding claims, characterized characterized that the duty cycle after calculation of the recording parameter and after a specified one has elapsed Delay time begins. 5. Camera according to claim 4, characterized in that the Delay time is 300 ms. 6. Camera according to claim 1, characterized in that the Switch on state of the light source (GD) by a Pulse series is interruptible, which specifies the recording parameter in binary code.   7. Camera according to claim 6, characterized in that the switch-on state after calculating the open parameters and after a predetermined delay is interruptible by the pulse series. 8. Camera according to claim 7, characterized in that the Delay time is 300 ms.