DE2054521C3 - 09/21/70 Japan 83119-70 Exposure control device for a camera - Google Patents

Description

Daylight and flashlight recordings
F-stop depending on the distance

a scene to be illuminated by flashlight The invention relates to an exposure control cutout is set and the exposure time direction for a camera corresponding to the upper leg Depending on the set aperture iyid attacked claim 1.

the brightness of the overall scene is controlled, If a pri-

characterized in that in a scene excerpt that is of particular interest (e.g. a per-

known way a variable resistance »5 son) relatively dark compared to the genre

(Λ3; Λ12) for setting the distance from the entire scene, which is primarily through the background

can be seen that a second photoelectronic is determined, it is already known the brightness of the

Component (PZ) to the exposure control scarf to enlarge scene excerpt by flash light

device is connected, which only the brightness of the recording with a suitable exposure and depth

Measures scene section, and that the exposure ^ao fenschenken to be able to carry out. With this

control circuit is designed so that the aperture knew exposure control device with a flash

(23) depending on the brightness and the automatic light and daylight control (German layout

Removal of the scene excerpt is controlled writing 1290805) for this purpose first the

(Figures 1 to 12). Aperture according to the distance and then the exposure

2. Exposure control device according to the preparation time according to the aperture and the brightness of claim 1, characterized in that set to the overall scene. In this case, however, the second photoelectronic component (PZ) is seen as a part that in certain cases an over-stepped photoelectronic component (P3) is exposed in the image of the scene section, which can affect the brightness of the overall, for example when the object brightness scene measures, and that these two photoelectronic 30 of the scene excerpt is still relatively large, see components (Pl, P3) with the input or, if the object brightness of the scene from a comparator circuit ( B) are connected, cut in the preparation and implementation of their output signal The setting of the aperture changes the exposure, especially if the exposure (23) after the ignition of the flash unit (D) corresponds to the exposure time for the exposure to daylight (Fig. 1 to 3). 35 is moderately long.

3. Exposure control device according to An It is therefore the object of the invention to provide an exposure control device 1, characterized in that a shutter control device of the type mentioned at the beginning is provided ( FIGS. 5 to 8). to improve in such a way that also by daylight

4. Exposure control device according to the brightness level to be brightened by flash light 2 or 3, characterized in that a 40 takes account of the scene excerpt. This variable resistance (Λ7; AU) with the task is indicated by the characteristic features Diaphragm adjustment ring of the diaphragm (23) is coupled, of claim 1 solved. Advantageous further and that the comparator circuit is one of the formations of the invention are the subject of the sub-brightness difference of the overall scene and the demands of the scene.

Internal section-dependent signal with a signal given by 45. The invention is to be explained in more detail, for example, with the aid of the drawing for both variable resistances (Rl; RU). It shows
compares correct signal in order to correct the setting of FIG. 1, a schematic representation of a shutter (23) corresponding to the brightness difference guide form of an exposure control device (FIGS. 3 and 4). measure of the invention,

5. Exposure control device according to An 50 Fig. 2 to 4 modified exemplary embodiment claim 4, characterized in that a GaI- the embodiment shown in Fig. 1,
vannmeter (M3) is connected to the comparator circuit. depending on the time, whereby also

6. Exposure control device according to responsive light-time curves of a flashlight device Claim 4, characterized in that display 55 are entered,

lamps (Ll, LZ) to the comparator circuit an- Fi g. 6 shows a circuit diagram of an embodiment according to

are closed (Fig. 4). of Fig. 5-1,

7. Exposure control device according to FIGS. 7, 8, 10 and 11 modified embodiment claim 3, characterized in that the molding of a device according to the invention,
second photoelectronic component (PZ) a 60 Fig. 9 a graphic representation of the voltage-time-determining circuit with a condensation curve on a capacitor,

tor (Cl) and the variable resistor Fig. 12-l a preferred mechanism for a

(RlZ) to adjust the distance connected exposure control device according to the invention,

sen, the output signal of a circuit Fig. 12-2 a modified embodiment of a

(/; DAX) is fed to the flash unit (D) 65 of the component shown in Fig. 12-1,

after a predetermined opening has been reached. In FIG. 1 there is a device 21 for limiting

of the diaphragm shutter (FS) to ignite (FIG. 6 of the angle of incidence, a diaphragm 22, its control

to 8.10). occurs through the incidence of light through the lens,

¹ T

or which is arranged separately, which is coupled to the objective diaphragm 23 and which is arranged in front of a photoelectronic component P4 of an electronic shutter. Light falls on a photoelectronic component P1 only from a scene section, while light from the entire scene falls on a photoelectronic component P3. Furthermore, there is a time-determining circuit A for the electronic shutter, an electromagnet MgI for controlling the shutter, a comparator circuit B for determining the difference in brightness between a scene section and the entire scene, and a control device CC for controlling the current through an ammeter Ml in accordance with a signal from the comparator circuit B provided.

The ammeter Ml controls with his hand the aperture 22 for the photo electronic component P4, and the aperture 23 of the lens 24. For the film speed and the distance, for example, variable resistors Rl and RA provided, and an electronic flash unit D, an output signal in response to the guide number of the flash unit delivered, which is triggered, for example, by the electromagnet MgI synchronously with the shutter. A variable resistor RA is coupled to an aperture ring, and a switch SO is connected in series with the variable resistor RA .

The mode of operation of the exemplary embodiment shown in FIG. 1 will now be explained in more detail below. A diaphragm is set by means of a signal from the flash device D. When the iris is adjusted manually, the switch 50 is closed and the variable resistor RA can be adjusted by rotating the iris adjusting ring. With the photoelectronic component F1 , the brightness of the scene section is measured through the delimitation device 21, while with the photoelectronic component P3, the average brightness of the entire scene is measured. The signals from the two photoelectronic elements P2 and P3 are fed to the control circuit CC via the comparator circuit B.

The ammeter M2 and the coupled diaphragms 22 and 23 are actuated by the signal from the control circuit CC, by the signal corresponding to the conductance of the flash unit D and by the signals corresponding to the film sensitivity and the distance and input by means of the resistors R1 and R3. The opening of the diaphragm is set to a corresponding opening, which corresponds to the difference in brightness of the scene section and the overall scene.

When the shutter button is pressed, the value of the light intensity both from the scene section and from the entire scene is determined by means of the opening of the shutter 22 by means of the photoelectronic component P4 and an exposure time of the electronic shutter is controlled by means of the time-determining circuit A , so that a daylight recording can be carried out automatically is.

The embodiment shown in Fig. 1 can be modified so that exposure is possible without a diaphragm correction, but with a correction of the flash light duration. If the embodiment shown in Fig. 1 is used with a single-lens reflex camera, a time-determining circuit corresponding to the circuit A can be coupled to a switch corresponding to the switch SO, the time-determining circuit with a, the variable wi-

the variable resistance corresponding to RA is connected if the camera has an aperture preset and a light measurement is carried out with the aperture open.

In the device in Fig. 4, two photoelec-

tronic components P2 and P3 with three connections and a further photoelectronic component P4 provided. The number of photoelectronic components can be reduced by a slight modification can be reduced by, for example, a

Switch with two components or only one component with three electrodes is connected. the The f-number can be determined and corrected automatically, semi-automatically or manually, as will be explained in more detail below.

ao The embodiment in Fig. 2 corresponds to that in Fig. 1 and in it the comparator circuit B and the control circuit CC are shown. Furthermore, there are again the photoelectronic components P2 and P3, a resistor R6 and a potentiometer RS

»5 planned; the resistance values of the photoelectronic components and the two other resistors together form a bridge circuit. A transistor TrI is used to determine the difference between the average brightness of the overall scene in front of the photoelectronic component P3 and the brightness of the scene section in front of the photoelectronic component P2. The output circuit of a further transistor TrI is connected in parallel to the variable resistor RA

switches. A switch S is closed only when the flash unit D is used; a voltage source El is also provided for the first actuation circuit.

In the following, the operation of the

In Fig. 2 illustrated embodiment explained in more detail. The transistor TrI is switched off when no correction is required due to a large difference in brightness between the scene section and the entire scene; however, it is switched on so that a correction can be made if there is a slight difference in brightness. When the aperture setting ring is rotated for pre-setting according to the guide number of the flash unit D, the film speed and the distance, the resistance RA is changed accordingly by its coupling with the aperture setting ring. One that corresponds to the default setting! Current then flows through the ammeter M2, unc the diaphragm 23 of the lens 24 and the diaphragm 2i in front of the photoelectronic component P4 are controlled according to the deflection of the pointer of the am perimeter M2.

When a correction signal is output from the bridge circuit, the transistors Tr]

and TrI conductive, whereby current through the ampere meter M2 with the help of the transistor TrI is controlled as a function of a required correction. When the flash unit D is connected to a device corresponding to this embodiment

is an automatic correction of the aperture value possible according to the guide number of the flash unit. The deflection of the ammeter M2 corresponds to this probably the brightness signal, which according to de

Brightness of the scene section at daytime or see component of the exposure control circuit of the Artificial light, for example in indoor shots, with a shutter that attracts relatively strong light is With the aid of the photoelectronic component P2 it is not appropriate for a satisfactory exposure, as well as the brightness signal that is appropriate and desirable when the closing sec- tion closes according to the average brightness of the gate of the shutter before the discharge of the entire scene is triggered with the help of the photoelectronic component flash device, i.e. before time T3. ments P3 is measured. To avoid this, the locking sequence

If the difference between the brightness of the can be delayed until the sector reaches a corresponding scene excerpt and the overall scene is low, the opening position is low. If this opening position is at or if there is no difference, 10 time point T1 is almost reached, the flash device of the transistor TrI will trigger a large deflection of the Am-. At the end of the lighting time of the flash device perimeter Ml, so that the locking sector can then close again by means of the deflected indicator, and a warning and locking of the locking device can take place in FIGS. 5-2 and 5-3. With the aid of a movement of the shutter at time 71, the ratio switch 51 can then be set to carry out a normally fast up to an opening FaI, which previously painted picture. At night it was determined to take a corresponding exposure, the resistances of the photoelectronic are to be initiated. At the point in time T1, which corresponds to the opening components P2 and P3 in comparison to FaI, the flash device is then triggered. Daylight photography very high, which is why the transis- After the time Tl is then the opening of the disturbing TrI and tri become non-conducting and the input * "aperture from the value Fai on Fa2 with a constant flow of the transistor TrI is negligible, so that speed is increased, and at the time Ti the camera is automatically switched on for a night photograph, the shutter is closed and is then set to. Time TA completely closed, so on this

In the modified embodiment in FIG. 3, a corresponding exposure is achieved. The time 73 at which the aperture correction is set manually is determined by various factors, the resistances of the photoelectronic influences, such as the brightness of the components P2 and P3, a resistor RS and an overall scene, the constant speed of the variable resistor Rl, which is coupled to the aperture sector 22 and the predetermined opening of the objective, a bridge circuit. FaI.

An ammeter M3 shows a deviation from the 30 With a low brightness and a large aperture; Here the pointer strikes in the positive or negative direction of the overall scene, in order to achieve both the exposure in its fully open position Fa3 until a size as well as the direction of the deviation is reached. The closing signs. If the diaphragm is changed, the movement of the shutter sector can then be accelerated with the aid of resistance R1 depending on the diaphragm setting device, change of direction and change when the current is through in FIGS. 5-4 and 5-5 a mode of operation corresponding to FIGS. 5-2 or the transistor 7> 3 equal to a current through a 5-3. Is applied to the Stel transistor TrA, the pointer proposes not, WO len FBI and F62 shown in FIGS. 5-4 and 5-5 is to be by a corresponding aperture correction arrival time Tl, the beginning and at the time 73, the is. Since, for shutter control, a limiting end of a fully open state of a switch resistor R9 is shown parallel to the photoelectronic shutter sector. In these cases see component P4 is connected, the processing time is then, in contrast to the cases in FIGS can be avoided in the end, aperture sectors the aperture. Serve. 45 aperture sectors in FIG. 5-4 and 5-5 can be of that

In the embodiment shown in Fig. 4 with the open state depending on the backward movement

game, which is slightly modified compared to Fig. 3, are movement of the shutter release by a film transport mechanism

small lamps Ll and L2 instead of the nismusod.dgl in Fig. 3. be completely closed. In the

used ammeter M3 used. If Fig. 5-2 and 5-4, the trigger becomes 0 at time

the aperture 23 of the lens 24 is depressed accordingly grain 50 and the sector begins to open

is yawed, transistors TrS and 7X »non-line movement from time 0 on with a

tend and the lamps Ll and L2 do not light up. constant speed. After the time Tl

If there are deviations, the transistor TrS or Tr6 gut the sector together with the aperture sector

and one of the transistors TrI or TrS conductive, actuated and then continues its opening movement,

with the corresponding lamp L1 or L2 lights up 55 In the cases of FIGS. 5-2 and 5-4, however, is one

and thereby the size and direction of the deviation a certain delay time between actuation

the correct aperture correction displayed, the shutter release and the actual shutter release.

will. The lamp Ll or L2 also serves as a warning device, which is why there is a risk that a

direction cannot be carried out in the event of deviations from a suitable recording. In the

Aperture correction. 60 Fig. 5-3 and 5-5 therefore measures are provided In Fig. 5-1 to 5-5 the time is on the abscissa in order to avoid this disadvantage,

and the size of the shutter opening on the ordinate. The circuit in FIG. 6 operates in accordance with FIG

applied. Here, the mode of operation is shown in FIG. 5-1 in FIG. 5-2. A photoelectronic one

of the clasp shown. If the embodiment component P4 has three electrodes; Furthermore, a capacitor C1, a photoresistor P2 and a are play as shown in FIG. 5-1

tet and when the trigger is pressed, another capacitor Cl opens. By means of a

the shutter at time 71 with a constant Ge switch S3 will turn off the timing circuit

speed. However, if on the photoelectronic the photoelectronic component P2 and the

7 8

Capacitor Cl can be turned on while using one. The light reflected from the overall scene switches 55 the time-determining circuit from which falls on the photoelectronic component / '4 and photoelectronic component PA and the connector through the shutter on the film in which the capacitor C2 can be switched on. A differential amplifier camera when the overall scene near HE DAI is the 5 place to control the opening movement. The circuit of FIG. 7 thus provides a shutter and, for firing the flash device, a differential amplifier DA 1 is used to control the low light intensity from the scene-closing movement of the shutter for precise exposure of the entire film surface even at rend. Potentiometric section and even with low light intensity from the dei meter resistors RN1 and RN2 , the overall scene is guaranteed with one another.

connected and are used to set the film sensitivity. Here, the resistor is used gerschaltungen I and II, in which diodes RNl is used to control the flash unit, while the Wi-WTl and UJTl with a double base and gederstand RNl is used to control the shutter. controlled silicon rectifiers 5CÄ1 and 5CR2 ver-An electromagnet MgI is used to control the öff- are used. In addition, a resistor / f 13 is connected in parallel to the capacitor voltage movement of the shutter and the ignition. A power transistor / Tl is much smaller than that of the photoelectroni-excitation of the electromagnet MgI . A component PA can be seen when the shutter 32 on the electromagnet Mg3 is used for the closing movement of the switch 55, which is no longer provided, for the shutter. Another achievement closes. The resistance value of the resistor transistor PT2 is used to excite the magnet ao des /? 13 is, however, much greater than that of the photo- MgS, furthermore an amplifier transistor AT is in the electronic component PA when the shutter 32 timing circuit for the shutter is open.

a voltage source E45 for the two timing elements. In the exemplary embodiment in FIG. 10, the two are

in the circuits, a main switch 546 and a photoresistors P1 and PA each with a connection

variable resistor RIl is provided, which is connected to each other »5, and transistors Tr9 and

adjusted according to the distance. A TrIO form a Schmitt trigger circuit. Here

Switch 50 is closed or opened when the transistor Tr9 is conductive, while the transistor

Recordings in the usual way without flash unit or TrIO is non-conductive, unless the controlled SiIi-

when flash photography is to be taken. ziumrectifier SCRl is switched on. If ever

In order to close the shutter before the trigger, the one assigned to the shutter in the lens

to prevent the flash unit from being used, if a second aperture 32 is first torn off, the photo-

Switch 52 is provided in parallel with switch 50. electronic component PA behind the panel of the

Then, when the switch 50 when taking flash photos of the lens in this state in comparison to the wi-

is open, the second switch 52 is still closed position of the photoelectronic component P1

sen. so that the closure after the ignition of the electrical 35 a high resistance. If then the switch

tronenblitzes is closed again. From the connected and the release switch is opened,

led reasons is the electromagnet Mg2, with the capacitor Cl via the photoelectronic

second switch S2 coupled. see component Pl and a variable wi-

In Fig. 7, a limiting device 31 is charged to the state Λ12.

Limitation of the angle of incidence provided behind 40 As can be seen from Fig. 9, reached after one

which the photoelectronic component Pl an- time rl the voltage on the capacitor the Wen

is ordered. A shutter 32 is the shutter FS el, whereby a double base diode UJT conductive

assigned, which can be a shutter. and the controlled silicon rectifier 5CÄ1

The photoelectronic component PA speaks when it is switched on: this then becomes the magnet

a light measurement through the lens. A change 45 MgS energizes and opens the shutter sectors, which

Such resistance Ä12 is assigned to the aperture 32 for certain information. Immediately after the

Functions such as the guide number, the film temp- time ti , the flash unit D is fired. To this

Sensitivity, the distance or the like. Provided, the photoelectronic component PS

Switches 53 and 55 are connected to capacitors Cl or directly by the flashlight of the flash unit D

C2 connected in parallel, while switches S4 or 50 hit, and thus the controlled silicon equalization

56 Voltage sources EA or ES dressing or dressing SCR! switched on and the controlled silicon

be switched. To open or close the converter SCRl with the help of a capacitor

Sectors FS are an electromagnet MgI or Mg3 Cl switched off, which then the transistor TrIC

intended. conductive and the transistor Tr9 becomes non-conductive, se

The mode of operation of the 55 so that the resistor Rl is practically ineffective Ali device in FIG. 7 will now be explained in more detail. First, as a result of this, the capacitor C1 is closed via the main switch 54, and when the resistance of the photoelectronic converter switch 53 is opened, the charging of the P4 begins again. If the controlled silicon capacitor Cl is switched off according to the brightness of the rectifier 5CÄ1, the Elek scene excerpt; by a trigger circuit I 60 tromagnet Mg5 to prepare for a closure, the electromagnet Mg2 is then switched off at time 71 triggering. In this way, it is then excited in Fig. 5-1. When the shutter sectors FS are opened at time i3, when the voltage across the cone, the flash unit is fired and the capacitor C1 reaches the value e3, the controlled SiI zeit-determining circuit is switched on by means of a wide-range rectifier SCRl and the locking trigger circuit II is actuated. The electromagnet 65 closed.

Mg3 is then generated at time 73 in FIG. 5-1

Pressed speaking of the brightness of the overall scene, see the scene excerpt and the overall scene isi

whereby then the closure sectors FS closed a transistor TrIl parallel to the resistor RIt

9 10

switched. In this case, the pre-tensioning is then applied in this way to the stop ring «j4 with the aid of one

the diode UJT changed by the transistor 7/111. the circuit in Fig. 7 similar sounding beta

If the voltage is over taken at the beginning of the discharge.

the diode UJT to control the transistor TrIl After the stop ring «4 see / ur time / 1 is adjustable, the time il for a synchronous switch starts to rotate, an electromagnet MgI, according to the opening of the aperture, simply rather the sector ring M holds, switched off and gives and freely selectable. In this way, he (M) then results free, whereupon the aperture ring bl through the correct exposure for the scene section. a spring 46 is turned quickly until a protruding signal is applied to the base of the flash unit on the base of the lever 45 on the diaphragm ring on the syndes transistor TrIl, automatic ¹⁰ chronkontakl Sj engages the diaphragm correction on the stop table corresponding to the l.ichtin- ring α4 is attached electrically insulated. This increases the intensity of the flash unit. . the shutter sector bl rapidly to a certain In Ausfühiungsiorni of Figure 11, the aperture FAI is opened and the opening of which determines the photo-Blendetuahl by means of an ammeter; electronic component P4zugeordneten diaphragm in the rest corresponds to the circuit configuration largely ¹ S 32entspricht opening the aperture FnI. If then, with the embodiment in FIG. 1, the contact Sj touches the protruding lever 45 by means of the pointer. If an ammeter MA is deflected, the flash unit is ignited via switch .Vf '. Stop 34 on the diaphragm 33 and the diaphragm 32 which has already been closed, and one is controlled. With the help of the photoelectronic components flash light recording with a diaphragm IaI durchgemente Pl and Γ3 gives the comparator circuit B * ° leads.

a correction signal corresponding to the background Then the sector ring bl rotates together lighting to the control circuit CC , which continues with the stop ring a4, the Hcmmdie measuring circuit controlled and a corresponding plant α6 and al is effective. As a result, the f-stop number for a flash exposure is set, the sector bl continues to be set with a constant Cieschwin. Immediately after pressing the trigger »5 open. If the electromagnet Mg3 is then energized in this state, the locking sectors at time / 4, the pawl d4 is quickly opened the Blen- closing the shutter is of the pawl denzahl, by a variable resistor dl released a pin be preset to the stop ring RA d3 which the Blendenein- 3 »a4 is associated with fast collar clockwise without the action, or it may be a automatic of the inhibitor a6 and al rotated by the strongly tensioned matic presetting by the signal from the return spring 44, whereby the aperture sector flash device D take place. f> 2 is closed. Then, when the trigger al freely in FIG. 12-1 is a mechanical structure of a is given, the Hemmwerk opens α6 and al on closure FS of the type shown in Fig. 7 overall 35 basis of its own spring force the second synchronous Displays, the operation of the curve in switch S / 'and closes switch S3. Fig. 5-2 corresponds. In this embodiment, the locking lever is then rotated clockwise by a trigger al, a locking lever a3, a stop ring, the pin d3 until it reaches a bevel of the a4, elements a6 and al of an escapement, a sec-pawl dl and through this again betrayed ring M, a Blendensekter bl, a locking lever 4o is gel. Although the Synchrondl, an intermediate lever d2, and switches S / connected in series are closed in this state, the second synchronous synchronous switch S / and Sf is provided. When the switch Sf is opened, so that the flash unit cannot be operated against the bias of a spring 40. The diaphragm 32 'in Fig. 12-2 is pressed down, it is guided by pins 41 and 42 is a modified embodiment of the diaphragm in a slot guide. Here, a «32 in Fig. 12-1, which is coupled to the diaphragm ring bl ge-actuating spring 43 for the stop ring aA and a. Furthermore, a holder 50, a return spring 44 is tensioned in FIG. 12-2. In a further lens 51 and a photoelectronic CDS element pressing the trigger a3, the locking lever a3 is provided, which are assembled so that they form a counter-clockwise through a pin a2 on unit. The part Pl 'of the photoelectronic the trigger al rotated, whereby the engagement with 5 ° component 52 is in the vicinity of the focal plane of the stop ring aA is canceled. The lens 51 and only receives the light from the scene deflection ring a4 then begins to cut counter-clockwise, while the other part PA 'of the component receives light from the entire scene in a clockwise direction at a constant speed when the diaphragm is below Inhibiting effect of the inhibiting mechanism a6 and al 32 'is opened further. That way one can turn. After a small angle of rotation, a 55 very compact version will be used. If switch S3 is open and the second switch S / 'for part PA' is completely shielded, the flash synchronization can be lowered. No need for switch SS .

In addition 8 sheets of drawings

Claims (1)

8. exposure control device "according to patent claims: spoke 7, characterized in that the circuit (/; D / 41) the operating switch (SZ) 1. Exposure control device for a cable of the shutter (/ ⁷ S) actuated,
mera with a first photoelectronic 5
Component containing exposure control circuit, in which to achieve properly exposed ■