DE2548493C3 - Exposure control device for a single lens reflex camera - Google Patents

Description

The invention relates to an exposure control device device for a single-lens reflex camera with an exposure measurement with an open aperture, with a according to the object brightness adjustable stop for the diaphragm, which determines the diaphragm opening, onto the diaphragm which is pretensioned in the direction of a closed diaphragm opening when the shutter is released is closed.

From DE-AS 17 97 310 an exposure control device is already known in which the object brightness t> o can be determined both with the aperture open and with the aperture stopped down. Based on the data received the desired aperture value is then set by adjusting a stop through which the Aperture opening of the diaphragm is determined when the diaphragm is opened when the shutter is released Position jumps to the position with the desired aperture.

The aperture of a camera is also already known

according to the measured object brightness by fixing the pointer of the exposure meter steer. The use of the pointer of a light meter for this purpose is due to the insufficient strength of the pointer, as well as due to the lack of reliability of this method disadvantageous.

From DE-OS 19 55 688 an exposure control device is already known in which at a preset exposure time the aperture is set by an electronic circuit that When the shutter is released by an electromagnet, the diaphragm ring is prestressed in one direction of rotation is released so that the aperture from the full aperture to smaller aperture openings can adjust. With the help of an electronic circuit, one of the required Diaphragm opening proportional to the time the electromagnet is de-energized again, so that a pawl closes the diaphragm ring locked again However, such a diaphragm control is not suitable for exposure measurement through the lens with the aperture open, since the measured value of the end of the screen is determined by the during the Measurement made adjustment of the aperture is falsified.

It is for this reason that automatic exposure control arrangements are also already included in a one-eyed one Single-lens reflex camera has become known, in which the object brightness in front of a movement of the mirror and the aperture is saved. However, such storage of the object brightness requires a storage capacitor. Such components are, however, with associated with certain disadvantages, such as B. a charge drain or a decrease in resistance to moisture

The present invention is now based on the object of designing an exposure control device of the type mentioned at the outset so that an automatic presetting of the aperture stop takes place

This object is achieved by the means characterized in claim 1

In the exposure control device according to the invention, the diaphragm setting member which determines the later diaphragm setting is set with a predetermined one Adjusted speed after this aperture setting member by pressing the shutter release has been released

Upon actuation of the shutter release, the electronic circuit generates one of the APEX-BIendenwert a signal proportional to the time through which the adjustment is carried out via the electromagnet of the aperture setting member is terminated. Only after the stop for adjusting the aperture setting has been set, then the aperture itself released so that it can adjust to the desired aperture. An essential one Advantage of the exposure control device according to the invention is that no capacitor for It is necessary to store a charge corresponding to the aperture value Aperture adjustment allows because the aperture itself remains in its open position until the actual The setting process for the aperture value is complete. The time between the release of the shutter release and the completion of the aperture setting to its predetermined aperture is kept extremely short that the setting time of the diaphragm setting member is a linear function of the APEX value of the

Aperture size is and that the termination of the movement of the aperture setting member with the beginning the movement of the diaphragm blades coincides.

In the following, the invention will be described in more detail with reference to a preferred embodiment shown in the drawing example are explained. In the drawing shows

Fig. 1 shows an electrical circuit of the new exposure arrangement and

Fig.2 shows the mechanical arrangement of the new View showing exposure arrangement in

If the exposure time of an automatic exposure device is set in advance when the time for setting the diaphragm is controlled, the control time for the movement of the diaphragm blades appears as an output of an electronic circuit. With ι> the vertex actuation, in which the object brightness (Bv) changes by three steps, the time (Tv) also changes by three steps, and accordingly the time must be a factor of 2 ³ to a longer time compared to time be changed before the change, m

For a more precise explanation of this fact, if the time is exponentially related to the brightness of the object, the relationship of the control time to the steps of the diaphragm mechanism must be selected in the following way. 2

It is a camera with eight stages of a shutter mechanism z. B. assumed from F 1.4 to F22. If the control time for the first stage is 1 ms, the time to control the aperture by eight stages is 256 ms (1 χ 2 ⁸ = 2ö6). As is well known, the aperture must be fully adjusted in a single-lens reflex camera before the shutter release begins. Therefore, if the control time for the aperture size is too long, the photographing operation itself becomes unstable. The aperture can therefore not be controlled by a time control as in a .jj method for determining the exposure time.

Due to this fact, the new exposure arrangement sets the control time for the diaphragm in a linear relationship to the brightness of the object. If, therefore, the control time is set to 1 ms for a step of Bv, the smallest diaphragm size, ie a diaphragm adjustment by eight steps, can be carried out in 1 8 = 8 ms.

In Fig. 1, a photodetector 1 and logarithmic compression diodes 2 and 3 are connected in series with a supply source 14, and the connection point a between them is connected to an operational amplifier 4 having a high input impedance. The operational amplifier 4 is constructed as an ordinary voltage regulator.

An adjustable resistor 5 and a logarithmic compression causing diodes 6 and 7 are connected in series with the supply source 14, and the connection point b between them is connected to a -, -, operational amplifier 8 with a high input impedance. The operational amplifier 8 is also designed as a voltage regulator.

An integration capacitor 9 has a reset switch 10 connected in parallel with it. The connection point d between the constant current source 11 and the capacitor 9 is connected to the non-inverting- <, -, the input terminal of an operational amplifier 12, while the output of the operational amplifier 4 is connected to the inverting input terminal of the amplifier 12. The operational amplifier 12 serves as a switch, its output being connected to a coil of an electromagnet 13 for controlling the shutter mechanism of a camera.

This circuit works as follows: If the voltage across the photodetector 1 is V \ and its resistance is R \, the current flowing through the diodes 2 and 3 is / |

The voltage V of the diode 2 in the forward direction

V =

K- T

• log -j * - + V ₁ , (2)

where Vs is the terminal voltage of diode 2 when the current is / V, and Kd \ e Boltzmann's constant, T is the absolute temperature and q is the charge of an electron.

If the current-voltage characteristics of diodes 2 and 3 are the same, the voltage being measured in the forward direction, then the voltage Va at point a is

Va

_{= 2} . (JLZ. , Eg Jl ₊ "Λ

where Va is proportional to the object brightness Bv .

At the same time, the current flowing through the diodes 6 and 7 is h

h = V ₂ IR ₂ , (4)

where the terminal voltage across resistor 5 is V ₂ and its resistance is R ₂ . The voltage V _b at connection point b is similar to expression (3)

= 2

iL + _Vs y

(5)

The operational amplifier 12 acts as a switch and switches its output voltage when the voltage at its non-inverting input terminal becomes equal to that at its inverting input terminal. If the time from the opening of the switch 10 to the reversal of the output voltage of the amplifier 12 is U, the current of the constant current source 11 is i, the capacitance of the integration capacitor 9 is C ₀ and the terminal voltage of the capacitor 9 when the amplifier 12 is inverted is Ko, then the following relationship applies:

V ₀ = Va- Vb = 2

LlL. log Jl . (6) 1 h

With the relationships (3) and (5) it still results

it = C ₀ -K ₀ (7)

and from the relationships (6) and (7) it follows

f ₌

2 ■ ^KT · los i a I.

(8th)

Since V _x = V ₁ results from the circuit structure, the following applies according to the relationships (1) and (4)

I ₁ Ji ₂ = R ₁₁ ¹ R ₁ ,
and relation (8) becomes with it

, -2

, og *

(9)

II)

Since the resistance /? Is the resistance value of the photodetector I which varies with the object wedge, and the resistance 5 is a resistance whose resistance value is set according to the exposure time and the film speed , R \ and Rj are determined as follows:

110)

where K \ is a proportionality factor, ) <\ the y-value of the photoresistor and Bv the object brightness in the APEX system.
The same applies

(11)

where Κ2 is a proportionality factor, y> a resistance ratio, Tv the exposure time and Sv the film speed in the APEX system.

If it is assumed that γ \ -Υ2 = γ , then from the relationships (9), (10) and (11) we get

f = · 2 · log _R

= (C _n i) ■ 2 - (A. "• T q) Flog - ^ A +; (Br + Sr - Tr) I.

where Av "= K logi 10.

is
■ = 0.5. so it turns out

^{: T} [2 log ^ + [Br + Sr + Tv) |. ⁴ 'f LK ₁

(12)

where C _n , i. K '. T, q fixed values and / Ci and Kj are intended for the control.

Is also d ^; e diaphragm size given by A ν , then A v = Bv + Sv-Tv and accordingly the relation (12) becomes

t = K ₃ (K ₀ + Ai).

(13)

Since K ₀ and K _{} are} constants of proportionality, the relation (13) indicates that the time t is proportional to the APEX aperture size Λ ν. B. adjusts the aperture mechanism step by step to smaller aperture sizes _b n so the time is increased step by step. Therefore, with an optical system from F 1.4 to 22 (8 steps), the time to reduce the aperture by eight steps, ie from 1.4 to 22.8 ms.

K ₀ plays the role of a standard level which combines the time t "5 and the diaphragm size Av . From relationships (10) and (11), this size is suitably set by controlling Ri and R2.

Fig. 2 shows the mechanical arrangement of the new exposure arrangement.

A support ring 20 for a diaphragm blade 21 is fastened in an objective not shown here. A wave 22 of the diaphragm blade 21 is rotatably mounted in a bore 20a. Another pin 24 of the diaphragm leaf 21 is located with a recess 23a in a diaphragm actuation ring 23 in engagement, so that the Diaphragm blade 21 around the shaft 22 by the rotation of the actuating ring 23 clockwise also in the Can be rotated clockwise to adjust the aperture to smaller aperture settings. The actuation ring 23 is provided with a rod 236 attached to it and extending towards the camera body extends to with the Ziingencnd 26a of a Blendcn stop arm 26 to come into engagement, so that an engaging part 266 of the stop arm 26 of a Tongue end 31a of an engaging arm 31 is hooked, whereby the spring force of an I ixier 25 is overcome, which acts in a clockwise direction on the actuating ring 23 works. A member 27 determining the aperture setting is in the! Provided teeth on its outer circumference and a pin 27a fixed to it is adjusted by an engaging lever 33 which is the force of a spring 30 overcomes. The pin 27.7 is also included the engaging part 266 of the stop arm 26 engaged. The stop arm 26 is provided with a pin 26c with an electrically insulating material is covered and the reset switch 10 in the position shown in FIG. 1 closes the circuit shown. The teeth of the link 27 are located engages with an escapement 28 of which 28a is a part. around at a suitable speed to be rotated. A ratchet wheel 29 arrives at its last step with a hook 316 des Engagement arm 31 of the stop arm 26 in engagement. In addition, the engagement arm 31 is provided with an anchor 32 provided with a suitable game, which is of a magnet 13 of the in F i g. 1 circuit shown is attracted to overcome the force of the spring 31c.

When the engaging arm 33 of the link is attached to a pin 33a, the end thereof is engaged with a protruding part 34a of a shutter release plate 34.

The operation of the arrangement will now be explained. When the shutter release plate 34 is moved downward in the direction indicated by the arrow by an external operation, the protruding part 34a pushes the pin 33a downward, whereby the engaging arm 33 is rotated counterclockwise. The engagement arm 33 is disengaged from the λ pin 27a to permit rotation of the link 27 in the counterclockwise direction. As a result of the meshing of the teeth, the ratchet wheel 29 also rotates. Since the reset switch 10 is opened at the same time, the operation of the functions shown in FIG. 1 circuit shown. After the period of time determined by the brightness of the object, the film sensitivity and the exposure time in the manner described above, the output signal of the amplifier 12 is inverted, whereby the magnet 13 is de-excited. As a result, the armature 32 is released and consequently the engaging arm 31 is rotated counterclockwise by the spring 31c and the stop arm 26 is released. At the same time, the hook part 316 comes into engagement with the ratchet wheel 29 and the part 27 which determines the aperture setting is stopped.

Thereafter, the stop arm 26 moves together with

the shutter operating ring 23 as a result of a spring 25. The end of the movement occurs at a point at which the engaging part 26b abuts the pin 27ίί on the member 27. At this point the aperture is set.

In other words, the camera works with the following sequence:

(1) The member 27 determining the aperture setting begins to close when the shutter is actuated move.

(2) The timer starts working Opening the reset switch 10.

( i) When the time set by the timer has passed, the magnet 13 is de-energized.

(4) The member 27 is stopped. At substantially the same time, the stop arm 26 begin, the Actuating ring 23 and the diaphragm leaves 21, of which only one is shown here, their movement to the aperture mechanics in the direction of smaller aperture sizes to adjust.

(5) When the edge 26b reaches the pin 27a, the last-mentioned mechanism stops moving.

(6) The mirror 39 then swings out of position with the aid of a known mechanism.

(7) The shutter begins to open.

In K i g. 2 enter the Bc / ugs / cichcn 35 Penlaprisniii. the He / ugszeichen) 6 an eyepiece, the Re / ugs / eichcii Yl a l'eldlmse and d; is Be / ugs / eichen 38 a ground glass.

1 sheet of drawings

Claims (4)

Claims; 1. Exposure control device for a single-lens reflex camera with exposure measurement with ϊ open aperture, with an adjustable stop for the aperture according to the object brightness and the exposure time, on which the aperture biased towards a closed aperture opening is closed ι ο when the shutter is released, characterized by a the Movable diaphragm setting member (27) carrying the stop {27a) , which is preloaded for a movement from a position corresponding to the full diaphragm opening in the direction of the decreasing diaphragm opening and can be unlocked when the shutter is released by a double-acting lock (31) actuated by an electromagnet (13) ), which in a first position locks the diaphragm (21, 23) in its open position and releases the diaphragm setting member (27) and after a time t in a second position releases the diaphragm and locks the diaphragm setting member (27) in its position, and by one Depending on the release of the shutter and after a time t proportional to the APEX aperture value determined by the object brightness and exposure time, an electronic circuit (FIG. 1) which actuates the electromagnet (13) emits a signal. jo 2. Exposure control device according to claim 1, characterized in that the aperture setting member consists of a rotatably mounted, with the aid of a The spring (30) is composed of a disc (27) pretensioned in a sewing direction. 3. Exposure control device according to claim 1 or 2, characterized in that the lock (31) consists of a double-armed lever. 4. Exposure control device according to claim 2 or 3, characterized in that the diaphragm (21, -to 23) is coupled to a lever (26) pivotable about the axis of rotation of the disc (27) which is used to adjust the diaphragm in each case up to the plant the stop (27a) formed on the disc (27) can be pivoted. «