DE2441620A1 - Electronic shutter for single lens reflex camera - uses large scale integrated circuitry combining all control functions - Google Patents

Abstract

The design of the large scale integrated circuitry is intended to provide an economic and compact system for accurate exposure control in a single lens reflex camera. The circuitry compensates for ambient temperature fluctuations and changes in battery voltage and makes provision for manual selection of various exposure parameters. A luminescent exposure value indicator is incorporated as well as control facilities using electronic flash illumination. The circuit stages consist of amplifiers, a logarithmic compressor and a correction stage for analogue signals which are then converted into digital pulses. These are stored, counted and processed in logic stages to provide the timing and indicator signals. The shutter is operated electromagnetically.

Description

Electronic shutter for a single-lens reflex camera Die The invention relates to an electronic shutter for a single-lens reflex camera.

In an electronic shutter for a single-lens reflex camera the amount of light entering through a photographic lens must be temporary or are currently saved. The amount of light extends over six Decades (10 ° to 106), which require complicated elements and complicated wiring would if a digital photoelectric conversion is attempted but which can be processed in a compact arrangement with just a single line, when analog processing is applied. On the other hand, if an analog voltage is stored, which for the formation of a shutter speed or exposure time is used, then digital storage is flawless in terms of performance Maintaining (the stored value) even after a longer storage period in the Compared to analog storage in a capacitor or something similar advantageous or preferable.

In addition, a digital display is preferable to a viewfinder as displays is, it can be seen from this that digital storage has greater advantages brings itself. When the stored value for determining a shutter speed or exposure time is taken, the time segment or period can be in Form of reference clock pulses are measured, which in turn has the advantage that any resulting error is only a fraction of a clock pulse, so that on this Way in comparison to an analog working method, in which an integration on a capacitor or something similar, even with an exposure over A high accuracy is achieved over a longer period of time.

The use of logic circuits enables it out in a simple way a logarithmic expansion of a logarithmically compressed, analog signal without the conversion or conversion accuracy as a result of changes or deviations from product to product, as a result of temperature changes, etc. is adversely affected, which is definitely the case with an analogous stretching or expansion may be the case.

The invention is therefore intended to provide an electronic shutter for a one-eyed Single-lens reflex camera with a facility to create a lighting system a display device caused errors in the photometry or light measurement to eliminate; Furthermore, a device is to be created according to the invention, which enables an exact and constant photometry or light measurement, if a flashing or flashing light source, such as a fluorescent tube, is used. In addition, a device is to be created to allow the circuit structure to simplify in the camera, thus an integrated circuit with a high degree of integration, a so-called LSI circuit can be used.

According to the invention is an electronic shutter for a one-eyed SLR camera created in which the through a photographic lens incident light is processed analog to an analog voltage create, which is used to form a shutter speed or exposure time will; the analog voltage is then converted into a digital value before being used subsequent control of the shutter is stored in a digital manner and the shutter speed or exposure time is displayed in a viewfinder. The invention also provides a device to - one by an illumination of the Display device caused errors in the photometry or light measurement Eliminate, and also provides a means to eliminate the instability of photometry or to eliminate light measurement if a flashing or flashing light source is used. Furthermore, according to the invention, the circuit structure is simplified, if the electrical circuit is an integrated circuit with a high degree of integration, a so-called LSI circuit, which is built into a camera can.

The invention is described below on the basis of preferred embodiments explained in detail with reference to the accompanying drawings. Show it: Figure 1 is a block diagram of the electrical circuitry of the electronic shutter for a single lens reflex camera according to the invention; Fig. Figure 2 is a schematic diagram of the display and photometric circuits which so are designed that an error in the light measurement or photometry as a result of a Illumination of the display device is eliminated; Figures 3 (a) to (e) are graphical representations to explain the operation of the circuit shown in Fig. 2, wherein in Fig. 3 (a) shows the waveform of a drive pulse which a display device illuminated, in Fig. 3 (b) the incident light from an object to be recorded, in FIG. 3 (c) the incident light which, when the display device is illuminated is generated, in Fig. 3 (d) an output signal from an amplifier (3), and in Fig. 3 (e) shows a photometric output signal present at an output P4 are; Figure 4 is a graphical representation of a change in light from one at 50 Hz operated fluorescent tube; 5 is a circuit diagram of the photometric circuit, in which the light measurement or photometry of a blinking or flashing Light source is stabilized according to the invention; Figures 6 (a) to (c) are graphs In order to explain the operation of the circuit shown in Fig. 5, where in particular in Fig. 6 (a) the waveform of an input signal, in Fig. 6 (b) the waveform of an amplified output signal, and in Fig. 6 (c) the waveform of an output signal are shown, which are smoothed by means of a capacitor is; FIG. 7 shows a modification of the circuit shown in FIG. 5; Figures 8 (a) through (c) graphs corresponding to those in Figures 6 (a) to (c); and FIG. 9 is a circuit diagram of an embodiment in which the electrical circuit according to the invention in the form of an integrated circuit with a high degree of integration, a so-called LSI circuit.

In Fig. 1, a light receiving element 1 for photoelectric Uses conversion of light transmitted by a photographic lens is, and is connected to a sensor amplifier 2, which its side to a logarithmic compressor circuit is switched on to create a geometric series, which represents the amount of incident light, to be converted into an arithmetic series, where then 1 in 0, 10 in 1, 102 in 2, 103 inp etc. is implemented. The outcome of the logarithmic compressor circuit 3 is with a temperature compensation - or compensation circuit 4, the output of which is fed to an analog arithmetic unit 5 which in turn is connected to a peak detector 6.

The logarithmic compressor circuit 3 is used to compress or Squeezing seclis decades to a low tension in the order of magnitude used by one or two volts. The information regarding the amount of light which has been converted into a voltage in the analog computing unit 5 (which for example 100 mV / 1EV) is according to the film speed value (ASA) and the aperture value (both for example 100 mV per step or level are set), with an analog voltage to form a shutter speed or an exposure time (in the following only exposure time is spoken of) is obtained, and which amounts to 100 mV per exposure time step. With With the help of the peak detector 6 it is ensured that a stabilized output for a light source, for example a fluorescent tube or lamp which flashes or lights up at a low frequency; also can with the peak detector, the light from the digital display or fluorescent tube or lamp, which are arranged in the viewfinder, are lifted or removed, as will be described later.

An analog switch 7 can be an automatically created one exit from the analog arithmetic unit 5, a manually set output from one the exposure time providing resistor 8 and an output from a battery 9 received. A 6-bit analog-to-digital converter 10 is designed to have a number digital outputs, e.g. creates a total of 42 digitized outputs, when the preset values of the film speed are increments or steps of a one-third step, with one f-stop in one-third increment or step and a one-third step for each exposure time from 1/1000 to 8 sec as well as two exposure periods under 1/1000 sec and over 8 sec which each lie outside the chained work area, i. e. (13 x 3 + 1) + 2 = 42.

The analog-to-digital converter 10 is assigned a pair of storage Signals from terminals 18 and 19 are supplied.

Here, the terminal 18 creates a signal to determine the storage, immediately before the light is picked up by the mirror, during the connection 19 is provided to supply a signal in order to store by means of one of external manual operation.

There is also a connection 20 for switching from automatic to manual operation intended. A logic circuit 11 receives the output of the converter 10 and conducts it to a counter 12, which receives the reference pulses from an oscillator 13 at the same time as the beginning or the start of the first curtain counts, when the stored digital information is introduced into the logic circuit 11 will.

Here, the arrangement is designed so that when the number or the Counter reading in the counter 12 with the value entered in the logic circuit 11 agrees, an electromagnet 14 is actuated to actuate the shutter.

The block 15 is part of the arrangement by means of which correct exposure is determined digitally by using the so-called zero method is used. By means of a display decoder 16 is a stored digital value representing an exposure time into a voltage for switching on a light emitting diode arranged in the viewfinder implemented in order to thereby to enable a digital display.

In Figs. 2 and 3, a control pulse shown in Fig. 3 (a) is applied to a pair of terminals P1 and P2 for intermittent and periodic, respectively Luminescence of a light emitting diode 21 applied, which indicates an exposure time. A light-absorbing element 22, for example a solar or solar cell with a fast response behavior or a high response sensitivity is arranged in the light path of the viewfinder to the sum of the incident light L of an object to be picked up (which is shown in Fig. 3 (b)) and the incident Measure light LR from the light emitting diode 21 (which is shown in Fig. 3 (c)). Element 22 is connected to the differential inputs of an amplifier 23 is turned on, which generates an amplifier signal V00 as shown in Fig. 3 (d) is. This signal is sent to a diode connected to the output of amplifier 23 24 applied, whereby the tips or apexes are cut off, and is then smoothed by means of a capacitor C, creating a photometric output signal VO is created. As shown in Fig. 3 (e), this is essentially the Influence of the light emitting diode on the output waveform eliminated.

The invention also provides a remedy for a flashing or flashing Light source. In Fig. 4, there is graphically a variation in light from a fluorescent tube or lamp operated at 50Hz. In an attempt it was found that a maximum exposure error was at an optimal exposure (an average / (error voltage) value) of +0.2 EV to 0.35 EV is enough if a picture taken with the help of a fluorescent tube or lamp in a room will; such an error can be neglected if the (entire) width of the film is being considered. If, on the other hand, the display of an exposure time in small increments or steps, for example in increments of one-third steps is reproduced, this presents a difficulty. To be constant and constant To create a display with a light source that illuminates at a low frequency or flashes, the responsiveness of the amplifier is reduced by a additional Capacitor or something similar degraded. On the other hand, with the invention a photometry or light measurement and a display alternately with the help of a Appropriate timing can be created to reduce the risk of Accuracy of light measurement or photometry to prevent caused by an illumination be caused by a light emitting diode or a similar display element can. To do this, the display must be displayed for the duration of the light measurement or photometry can be suppressed while the photometric output for the duration of the display must be switched off, which means, however, that by a good response sensitivity of the amplifier the error is reduced to a minimum.

To meet these two contradicting demands, is provided according to the invention that the first half of the amplifier characteristic has good responsiveness to allow accurate timing of the Ensure display and photometric phesis during the second half of the Amplifier characteristic has a reduced sensitivity in which the chopped or broken waveform for timing and consequent the light source that lights up or flashes at a low frequency pulsates Current can be smoothed by means of a capacitor, thereby changing the Limiting deflection to, for example, +1/6 EV.

5 is a circuit diagram of the peak detector according to one embodiment of the invention shown. Receiving an input voltage Vin from a light Element, for example a solar or solar cell, etc. is by means of an amplifier 34 amplified and then passed through a diode 35 to charge a capacitor C, so as to produce an output voltage Vout. As shown, will a time control pulse is applied to an input T to enable lighting or a lighting up or a luminescence of the light emitting diode indicating the exposure time and at the same time the timing pulse is applied to the base of a transistor TR created so that it becomes conductive. This way it becomes the non-inverting Input of amplifier 34 shorted to terminal -V, and thereby then the photometric output is switched off. This then results in the amplified signal of amplifier 34 as shown in Figure 6 (b).

When the output of the amplifier is detected by means of the diode 35 and is sensed and smoothed by means of the capacitor C, the output signal is Vout as shown in Fig. 6 (c). With the help of such a circuit arrangement the light measurement or photometry can be precisely timed, whereas the ripple still present at the entrance is eliminated, so that in this way a stable and constant display is enabled.

In the circuit shown, the diode 35 is forward biased operated when the capacitor C is charged, whereby the time interval from turning the circuit on until a predetermined voltage is obtained to on Interval reduced or decreased in the order of magnitude of about 4 msec.

is shortened.

Although the average or mean value of the low-frequency Output (where this average or mean value creates optimal exposure) with regard to the peak rectification of the output used results in eigr errors, this error remains when using a fluorescent light source in one Space in a range of + 0.3EV and is negligible if the width of the Films is being considered.

Another embodiment of the invention based on the average is shown in Fig. 7, where a timing pulse is applied to a terminal g created to ensure precise timing of the display and photometry or To control light measurement. A photometric input with a waveform like her shown in Fig. 8 (a) becomes a pulsating current having a waveform amplified, as shown in Fig. 8 (b), before using a capacitor C is integrated to provide an average; in this way then becomes a Output voltage Vout is generated as shown in Fig. 8 (c). A certain one Output is obtained by multiplying this mean by f / duty cycle or 2 in obtained from the example shown. Although this method is a larger time interval from switching on the circuit to the point in time at which a certain voltage is obtained, is thereby a greater one Accuracy than created with the tip detector method.

As stated above, in the electronic shutter according to of the invention in which, as described in connection with Fig. 1, a device is used for setting or determining a storage, a storage defining or determining signal, a signal that triggers an electromagnet and applying a control signal, all signals being applied via plug pins which must be connected to a so-called LSI unit, i.e. a unit with a high degree of integration are appropriate. When the above electrical circuit is designed as an integrated unit with a high degree of integration The plug-in pins result in higher costs and a less compact structure. One Enlarging or lengthening a single pen can prevent the built-in Unit in a required size is prevented by doing this is that the integrated unit because of the requirements on packing density i.e. the accommodation of as many elements as possible in a small space on a given one Place is housed in a camera. Consequently should, if the electrical circuit is a so-called LSI unit, i.e. an integrated Unit is to be carried out with a high degree of integration or group integration, which Number of pins reduced to a minimum. In Fig. 9 it is therefore shown that if the electrical circuit of Fig. 1 is in the form of an LSI unit, i.e., as a Integrated circuit is executed, the control pin on which the storage defining or determining signal is applied, as well as the control pin to which a signal triggering the electromagnet is applied are used in common.

According to the invention, the LSI or integrated circuit has a the storage determining or determining unit 44 and a period converter 46 in addition to the logic circuit shown in FIG. The exit of the period converter 46 is connected to the base of a transistor via a resistor R1 Tr 2 turned on, the collector of which is connected to a control pin A. The pencil A is also connected to a voltage supply line Vcc, so that on this Via the pen Atier the storage-defining device 44 a voltage is fed. The pin A is also connected to the base of a through a resistor R2 Connected to transistor Tr1, the collector of which is connected to an electromagnet Mg is which is used to move and shift the second curtain of the shutter is provided. A resistor R3 is between pin A and the power supply line + E switched while a normally closed switch SW1 between the power supply line -E and pin A is switched. The transistor Tr1 is also via its emitter connected to line -E.

In addition to the pin or pin A, there is another pin or pin B is provided in the integrated unit, the so-called LSI unit. Pin B is with a normally closed switch SW2 and a resistor R4 connected; here the arrangement is designed so that when the switch is opened SW2 a control signal is applied to the period converter 46.

The switch SW2 is opened when the first curtain closes runs or is moved. It should also be mentioned that the switches SW1 and SW2, the electromagnet Mg and the resistors R2 to R4 outside the integrated unit, the so-called LSI unit are arranged. The switch SW1 can by means of a Locking with an upward movement or with a folding up of a sliding one or pivotable mirror in the camera can be opened to the photographic Release way. If it, i.e. the switch SW1, is open, this will be the storage defining signal and the trigger signal for the electromagnet Mg to the pin A created.

When a shutter release is pressed during operation will, To take a picture, the movable or foldable mirror folds down above to open and release the photographic path. Because of such Pivoting movement, the switch SW1 is then opened, whereby the potential at the Pin A goes high, which is a storage setting as well creates a signal that triggers the electromagnet.

The signal defining the storage is then sent to the corresponding Means 44 applied to actuate this while the solenoid The triggering signal is applied to the base of the transistor Tr1 via the resistor R2 so that it becomes conductive and thereby the electromagnet Mg is actuated. When the electromagnet Mg is energized, it becomes the second curtain of the shutter forced to walk or move while the first curtain over the picture format runs and initiates an exposure.

When the first curtain moves, the switch SW2 is opened, whereby a control signal is fed to the period converter 46, which then begins count an exposure period; if then the count in the converter 46 corresponds to a stored value, then the output of the 'period converter inverts 46 goes high, causing the potential at pin A to go low Switches level, whereby the passage through the transistor Tr1 is interrupted and this one not is more conductive. If the transistor Tr1 does not is more conductive, the electromagnet Mg is de-energized, whereby then no compulsion or Pressure is exerted more on the second curtain of the shutter, so that this then immediately begins to run and with a corresponding shutter speed the recording process ends. In the circuit of FIG. 9, the resistor R3 can also be accommodated in the integrated unit, the so-called LSI unit.

- patent claims -

Claims (8)

Claims 1. Electronic shutter for a single-lens reflex camera, g e k e n n n z e i c h n e t by an analog computing device (5) for changing an analog output from a light receiving element (1) corresponding to FIG set film sensitivity and the aperture values to an analog voltage to obtain, which forms a corresponding exposure time, by a device with an analog-to-digital converter (10) to convert the analog voltage into a digital one Implementing the value and temporarily storing the digital value through a facility with a logic device (11) and a period counter (12) to get from the stored Value to obtain an exposure time, and by a device (16) for a digital display of the exposure time in a viewfinder of the camera. 2. Electronic lock according to claim 1, characterized in that 'g e k e n n it is noted that the display device is a luminescent device (21). 3. Electronic shutter according to claim 1, g e k e n nz e i c h n e t through narrow device (8), with which an exposure time is set by hand can be. 4. Electronic shutter according to claim 2, g e k e n nz e i c h n e t by a device for an intermittent luminescence of the luminescent Display device (21), and by a device (23) to light up or the flash of light from the display device as well as the incident light from an object to be picked up and around the amplified output to feel in an inverted form and to smooth out the perceived outcome. 5.Elektrodddher closure according to claim 2, g e k e n nz e i c h n e t by a, device for an intermittent luminescence of the luminescent Display device, and by a device (TR) for switching off a photometric Value obtained by the light receiving element during the interval during which the luminescence of the display device takes place. 6.Electronic lock according to claim 5, characterized g e k e n n z e i c h n e t that means (34) for amplifying a pulsating output provided by the light receiving element, and that the amplifier means (34) first and second stages with good and lower responsiveness, respectively for the pulsating output. 7.Elektronic lock according to claim 1, characterized g e k e n n z e i c h n e t that the logical device (11), one the storage defining device (44) and a period converter (46) in a circuit with are integrated with a high degree of integration. 8. Closure according to claim 7, g e k e n n z e i c h n e t by a electrical switch (SW1) which is opened or closed according to a signal to generate the pivoting movement of a pivotable mirror in the camera, and by means (Tr1) around the signal from the switch (SW1) at the end of the period conversion to interrupt, the signal from the electrical switch both as a die SpeicheTung-defining signal as well as a shutter triggering signal are used will. Blank page