DE3213115A1 - Camera having an automatic TTL focusing device, and lenses therefor - Google Patents

Abstract

The invention relates to a camera having a camera body, a taking lens that can be detachably mounted thereon and an automatic focusing device which for the purpose of focusing on an object enables the taking lens to be adjusted by arranging for a focusing detector to which the light passing through the taking lens is applied to determine the magnitude of the deviation between a predetermined focal plane and the actual imaging plane of the object and to transmit an output signal linked thereto to a drive device for adjusting the lens. Provided in this connection are: a) a device on the lens side which derives from the drive magnitude of the drive device a signal relating to the magnitude of the adjustment of the imaging plane, as the latter is the consequence of a lens adjustment, it being the case that this device for generating signals relating to the magnitude of the imaging plane adjustment is designed for the purpose of generating the same signal for the same magnitude of the image plane adjustment independently of the type of lens respectively attached to the camera, and b) a device for controlling the drive magnitude of the drive device and which responds to the signal relating to the magnitude of the imaging plane adjustment and to the output signal determined for the focusing detector.

Description

description

Camera with automatic TTL focusing device and lenses therefor The invention relates to a camera with automatic TTL focusing device, wherein light that has passed through an attached interchangeable lens is measured using the The measured value of the focus state of the lens is assessed and then automatically the focusing is accomplished. The invention also relates to a Interchangeable lens for such an automatically focusing camera.

(TTL generally stands for measurement through the lens the lens).) For example, U.S. Patents 4,185,191 and 4,264,810 describe a TTL focus detection device for measuring through a taking lens passed light and determining the amount of deviation of the actual object image plane of a predetermined Focal plane of the taking lens, for example the film level. The taking lens can then be brought into focus through a with With the help of a drive adjustment of the focusing lens system -des Taking lens by a size corresponding to the detected size of the deviation the mapping plane. In detail, see FIG. 1, the deviation Ax is the actual Object imaging plane 3 from the predetermined focal plane 2 of the taking lens 1 is detected, and the taking lens 1 is rotated by a predetermined amount d adjusted according to the size of the deviation Ax, so that the image of the object is generated on the predetermined focal plane 2. Of course, the size of the image plane deviation can Ax cannot usually be determined very precisely for large values of bx, therefore the taking lens gradually becomes close to the focus by repeating the adjustment of the deviation size and the taking lens. However, if a motor or the like according to the amount of image plane deviation is driven to move the focusing lens group of the taking lens, can be the transmission ratio of a transmission system that drives the engine or the like transfers to the focusing lens group, from interchangeable lenses to interchangeable lens vary. Likewise that of an image plane deviation x x associated size of the lens adjustment movement td from interchangeable lens to interchangeable lens be different. The size of the lens adjustment depends, for example, on the Focal length of the lens or on whether the lens as a whole or when focusing only adjusted a part of its lens elements in the case of the remaining lens elements being fixed (total lens adjustment or

Partial lens adjustment). If accordingly for the same amount of image plane deviation the same drive variable (manipulated variable) of the motor or the like for each interchangeable lens or the same amount of displacement of the focusing lens group of the taking lens are selected, one depends on the type of interchangeable lens used There is a problem in that accurate focus is impossible or for focus it takes far too long.

The object of the invention is therefore to provide an automatic TTL focusing device to provide for a camera that links the adjustment variable of an interchangeable lens with the determined size of the image plane deviation for each interchangeable lens able to optimize, and to provide an interchangeable lens for this.

According to the invention there is provided a correction signal generating device for generating a correction signal corresponding to the type of interchangeable lens, for example corresponding to the transmission ratio of the transmission system for the focusing lens drive device, interchangeable objects provided on the active side. Taking this correction signal into account in addition to the size of the image plane deviation, such as this from a camera-side TTL focus detecting device is detected, the amount of focus lens shift controlled so that the resulting from the adjustment of the focusing lens size Image plane shift is equal to the size of the image plane deviation. Accordingly is even if the interchangeable lens is exchanged for another, none on the camera side further action is required and it can provide accurate focusing can be achieved for each interchangeable lens, with the size for all interchangeable lenses the adjustment of the focusing lens is controlled so that, as described, the size the image plane shift is equal to the size of the image plane deviation, whereby the focus of the respective lens can be done very quickly.

The invention is characterized in the claims and below described in detail with reference to the drawing; it shows: the already mentioned Fig. 1 the relationship between taking lens shift and image plane shift, 2 shows a schematic sectional view of a camera with an interchangeable lens attached, corresponding to a first embodiment of the invention, FIG. 3 a schematic Oblique view of the interchangeable lens according to FIG. 2, FIG. 4 shows an oblique view of a modified embodiment of the image plane adjustment variable signal generating device, and Figs. 5 to 7 are block diagrams showing a second, third and fourth, respectively Embodiment of the invention.

As shown in Fig. 2, is a single lens reflex camera 10 provided with an attached interchangeable lens 11. The interchangeable lens 11 is provided with a focusing lens 12, further with a motor 13 as Drive source, a transmission system 14 for transmitting the motor drive to the focusing lens 12 for their adjustment in the direction of the optical axis for the purpose of focusing, as well as with an imaging plane displacement magnitude signal generating device for generating a signal that represents the magnitude of the displacement of the object imaging plane, how this is the result of an adjustment of the focusing lens 12. The motor 13 and / or the transmission system 14 form the focusing lens drive device. In Fig. 2 is only a single focusing lens 12 as the optical system of the interchangeable lens 11 shown, but actually to summarize the optical system a plurality of lens elements.

The focusing lens 12 refers to that part of the lens elements which is adjusted for the purpose of focusing; there are interchangeable lenses where all lens elements correspond to the focusing lens, but also interchangeable lenses, in which only part of the lens elements correspond to the focusing lens. The imaging plane adjustment size signal generation device 15 generates a signal that represents the amount of movement of the image plane (Fig. 1), like this from the adjustment of the focusing lens 12 on the basis of the number of revolutions of the engine 13, the BewecJungs «roPe of the transmission system 14 or the displacement amount of the focusing lens 12 results. This mapping plane adjustment variable signal is standardized for each interchangeable lens so that it has the same value for the same Adopts imaging plane adjustment variable also with regard to other interchangeable lens types, in which the imaging plane adjustment variable with respect to the transmission ratio of the transmission system 14 or the adjustment variable unit of the focusing lens 12 differs from lens to lens.

On the other hand, the body 10 has the single lens reflex camera a mirror 17, which can be quickly raised and folded down, for reflecting the through the taking lens Light that has passed into the finder optical system 16, for example into the pentagonal prism same. The folding mirror 17 leaves a part of that originating from the taking lens Light through, and this let through part is seen on one behind the mirror 17 located auxiliary mirror 18 directed. The light reflected on the mirror 18 arrives at a TTL focus detector 19, which is arranged on the bottom of the camera is.

The detector 19 measures the light which has passed through the taking lens and represents the size of the deviation + Ax of the actual object image plane of a predetermined Focal plane conjugating to film plane 20 is fixed. The sign of this deviation variable Zx indicates whether the object imaging plane in front of or behind the predetermined focal plane, and the amount of ßx gives the size of the deviation again.

A control device 21 receives the mapping plane deviation amount as input signals + Ax which is the output of the focus detector 19 and the output of the imaging plane shift amount signal generating means 15. The control device 21 generates a control output signal for rotating the motor 13 in the normal direction of rotation or in the opposite direction of rotation depending on the sign of the image plane deviation + x and stops the motor 13 when the output of the signal generating device 15 a value. assumes that is representative of the magnitude of the image plane shift Ax is.

The mode of action is as follows.

In the operation of this automatic focusing device, the focus detector measures 19 shows the light that has passed through the taking lens and represents the amount of deviation in the image plane + Ax firmly. The control circuit 21 rotates the motor 13 in normal or in the opposite direction, depending on the sign of the image plane deviation. The rotation of the motor 13 causes an adjustment of the focusing lens 12 along the optical Axis in the direction of focusing with the intermediary of the transmission system 14. In accordance with this adjustment of the focusing lens 12, the object imaging plane approaches of the predetermined focal plane, and the imaging plane deviation amount signal generating means generates an imaging plane adjustment variable signal which indicates the size of the adjustment represents the image plane on a real-time basis. This signal becomes the control device 21 sent. When this imaging plane adjustment amount signal has a value corresponding to Assumes Ax, the control device 21 stops the motor 13. That way drifts the control circuit 21 drives the motor 13 in a direction of rotation on the basis of the sign of the imaging plane deviation + A x, like this one from the focus detector 19 is detected, the focusing lens 12 moves and then stops the motor 13 on when the output of the imaging plane displacement amount signal generating means 15 indicates the fact that the resulting amount of image plane shift is the same ß x is. Accordingly, the focusing lens 12 can be moved so that the image unseen around the same size is adjusted as the size of the focus detector 19 was found to be the imaging plane deviation. As mentioned, the mapping plane adjustment amount signal generating means is 15 each interchangeable lens 11 standardized so that they have the same signal for the same Size of an image plane adjustment with regard to each interchangeable lens generated, regardless of the transmission ratio of the transmission system 14 or the size of the adjustment of the focusing lens 12 and the resulting Image plane adjustment. It can therefore, even if any interchangeable lens 11 is on the camera body 10 is attached, the camera-side control device 21 the motor, in response to the signal from the signal generating device 15, stop.

The following is a special embodiment of the structure of the interchangeable lens 11 described.

As shown in Fig. 3, are on the camera-side mounting surface lla of the lens 11 connections T1, T2 and T3 for the transmission of signals between Lens and camera provided. The motor 13 receives the control output of the camera-side control device 21 via the connections T1 and T2, the rotation of the Motor 13 will via reduction gears 140, 141 and 142 a reduction gear 143 is transmitted. This last transmission gear 143 rotates around the lens, and this rotation is carried out by a spindle drive, not shown or cam mechanism in rectilinear movement of the focusing lens 12 of the taking lens implemented in the direction of the optical axis. The reduction gears described above 140 to 143 and the spindle drive or the like together form the transmission system 14. A mapping plane displacement amount detector pattern 150 is on the face of the gear 141 is provided, in the form of four equal, alternately high and low reflecting circular sectors 150a and 150b. A light source 151 directs Light on a specific part of the pattern 150, and a light receiving element 152 receives the reflected light. The light receiving element 152 produces two Pulses per full revolution of the pattern 150, as a result of one rotation of the gear 141. This pulse output is called the map plane shift magnitude signal sent to the camera-side control device 21 via the connection T3. The pattern 150, the light source 151 and the light receiving element 152 together constitute the imaging plane shift amount signal generating means 1 5.

As mentioned, the imaging plane displacement magnitude signal generating means is 15 of each interchangeable lens 11 so constructed that it receives the same image plane adjustment variable signal, namely the same number of pulses for the same image plane adjustment. An example of such a structure will be described below.

Let there be two automatically focusing interchangeable lenses of one focal length viewed from 50 mm or 100 mm.

For the two interchangeable lenses it is assumed that the size of the Adjustment of the image plane from the smallest object distance to the object distance Infinite 4 mm or 9 mm, that the angle of rotation of the spindle drive of the smallest to largest object distance is 600 and that the reduction ratio from the gear on which the pattern is applied to the last gear 1/120 or 1/180 amounts to. Furthermore, it is assumed that because of the requirement of a sufficient automatic focusing accuracy, at least one pulse for an image plane adjustment variable of 0.1 mr is necessary. The pattern 150 is determined on the basis of these conditions of the two interchangeable lenses as follows. For the interchangeable lens the focal length of 50 mm is the reduction ratio 1/120, and the angle of rotation of the spindle drive from smallest to largest (infinite) object distance 600. The pattern 150 therefore makes 20 full revolutions when the focusing lens is from the smallest object distance is adjusted to the object distance infinite. Since the size of the image plane adjustment is 4 mm for this, an image plane adjustment results of 0.2 mm per full revolution of the pattern 150. Accordingly, by dividing, one obtains a circle in four sectors with alternating low and high reflectivity, as shown in Fig. 3, an imaging plane shift amount signal of one pulse per 0.1 mm of image plane adjustment.

The focal length is obtained in a similar way for the interchangeable lens of 100 mm by dividing a circle into six sectors alternately high and low reflectivity, a pattern that is used as the imaging plane shift amount signal one pulse per 0.1 mm of image plane adjustment.

As mentioned, through a suitable choice of the transfer ratio (Undercut ratio) of the transmission system and the number Sectors of the pattern for each interchangeable lens, the image plane adjustment variable signal the same for all interchangeable lenses per imaging plane adjustment unit be made.

A larger number of pulses per unit size of the imaging plane adjustment leads to better focusing accuracy, it is therefore desirable to apply the pattern 150 in the transmission system in the vicinity of the motor 13. By Applying the pattern 150 to the first reduction gear 140 belonging to the motor 13 is immediately downstream, and by choosing the transfer ratio such that the same mapping plane adjustment amount for the same number of revolutions of the motor is obtained for each interchangeable lens, the gears of the first can Level of all interchangeable lenses and their patterns are made the same.

In the above example, the imaging plane displacement amount is signal generating means 15 composed of the reflection pattern 150, the light source 151 and the light receiving element 152. However, such training is not mandatory. The signal generating device can also consist of a light transmission pattern and a light source on the one and a light receiving element built on the other side of the pattern be, or from a magnetic pattern at a suitable point in the transmission system 14 is attached, and a detector therefor. With a further possibility of modification, which is shown in Fig. 4 is a pattern of electrically conductive Parts 154a and electrically insulating parts 154b, which are on the outer periphery of a Disc 153 formed in one piece with a gear wheel of the transmission system 14 may be applied, with a pair of switch contacts 155a and 155b, which together a switch 155, brought into contact with this pattern, and an imaging plane shift magnitude signal by turning the switch 155 on and off by the contact between the two Switching contacts and the electrically conductive or non-conductive part 154a or 154b can be generated. The picture level adjustment size signa also needs not to be limited to the digital signal described above, it can also be a Be analog signal.

In the arrangement described, the control output signal is offset of the control device 21 in accordance with the output of the focus detector 19 the motor 13 rotating in one direction via the connections T1 and T2. . With this rotation, the focusing lens 12 becomes under mediation the reduction gears 140 to 143 and the spindle drive or the like. Included the light receiving element 152 generates pulses in a number corresponding to the number Pattern 150 turns.

This pulse train is transmitted to the camera-side control device 21 the terminal T3 supplied. The control device 21 counts the number of incoming ones Pulses and stops the motor 13 when the count value of the magnitude of the image plane displacement Ax corresponds to.

In the second embodiment shown in Fig. 5 are in the dashed box 10 located components provided on the camera side, while the components located in field 11 framed by dashed lines on the side of the interchangeable lens lie. The TTL focus detector 19 and the control device 21 are identical with those shown in FIG. A focusing lens driver 22 controls the adjustment of the focusing lens 12 in response to the control output of the Control device 21 and corresponds to engine 13 and transmission system 14 of FIG 2. A converter device 23 receives the drive quantity of the drive device 22 either directly from the drive device 12 or indirectly from the focusing lens 12 and puts this size in an electric one Signal around, for example in pulses, the number of which corresponds to this size. A correction signal generator 24 generates a correction signal according to the type of lens attached, for example, according to its transmission ratio of the objective-side transmission system. This correction signal can either be an electrical signal or a mechanical one Be signal. A correction device 25 corrects or standardizes the electrical Output signal of converter device 23 into an imaging plane adjustment variable signal, the same value for different interchangeable lenses for the same size of the Assumes imaging plane adjustment on the basis of the correction signal. Of course if the correction signal is a mechanical signal, the correction means 25 convert this signal into an electrical signal beforehand. The correction device 25 can also be provided on the interchangeable lens side.

The control device 21 stops the focusing lens driving device 22 when the mapping plane offset amount signal assumes a value equal to the Size of the imaging plane deviation detected by the focus detector 19 ax corresponds to. In this way, the focusing lens 12 is adjusted automatically, so that the size of the imaging plane adjustment is the same the established The size of the mapping plane deviation & c.

The converter device 23, the correction signal generator 24 and the correction device 25 together form the imaging plane adjustment quantity signal generating device.

Considering the correspondence between the structure of the imaging plane adjustment amount signal generating means 15 of the first embodiment and the converter device 23, the correction signal generator 24 and the corrector 25 of the second embodiment are examined, then the pattern 150 can be said to correspond to the correction signal generator, furthermore the light source 151 and the light receiving element 152 correspond to the converter means and the combination of pattern 150, light source 151, and light receiving element 152 corresponds to the correction device. That is, in the imaging plane shift amount signal generating device of the first embodiment are the converting means and the correcting means functionally an integral whole, and the drive size of the lens drive device 22 is standardized and converted into an electrical signal the Base of the output signal of the correction signal generator.

This takes place both in the first and in the second exemplary embodiment the control according to the principle of a so-called closed control loop which controls the focusing lens drive means 13, 14, 22 is determined by determining their drive size and based on the Worth.

Third and fourth embodiments are shown below described, in which a converter 26, the detected output signal + Ax of the TTL focus detector 19 to a signal + ix ', according to the type of interchangeable lens attached on the basis of the correction signal of a correction signal generator 24 on the Interchangeable lens side 11.

A control device 21 generates a control signal for controlling the Drive amount of the focus lens drive device 22 corresponding to the converted one Signal ## x '.

The lens driving device drives in accordance with this control signal 22 the focusing lens 12 by a size for which the size of the image plane adjustment becomes equal to A x.

If, as in this example, the control output signal the Control device 21 controls the drive amount of the focusing lens driving device 22 controls, a pulse motor can be used as the drive source for the drive device 22 can be used and the design can be made so that the control device 21 an output pulse train is generated as a control output signal, the pulse number of which corresponds to the converted signal corresponds to 6 x '.

7 shows a fourth embodiment as a modification of the third Embodiment. There the control device receives the variable as an input signal of the imaging plane deviation + βx, such as this from the TTL focus detector 19 is detected and generates a number of pulses corresponding to this. A Converter 27 converts this number of pulses into a number of pulses corresponding to the one applied Interchangeable lens type based on the output signal of the correction signal generator 24. The pulse motor of the drive device 22 drives the focusing lens 12 so that that the imaging plane is adjusted by Ax, as a result of the output impulses of the Converter 27.

In the embodiments described above, although the drive source is for example a motor on the lens side provided she can but also be provided on the camera side.

Claims (6)

Claims 1. Camera with - a camera body, one on it detachably attachable taking lens and - an automatic focusing device, an adjustment of the taking lens for focusing on an object thereby allows a focus detector to be passed through the taking lens passed light is applied, the size of the deviation between a predetermined Focal plane and the actual imaging plane of the object are determined and a thus sends a linked output signal to a drive device for lens adjustment, e k e k e n n n z e i c h n e t by a) an objective-side device that consists of the Drive size of the drive device a signal about the size the adjustment of the imaging plane derives how this is the result of a lens adjustment is, this imaging plane displacement amount signal generating means is designed to use the same signal for the same level of image plane adjustment independently of the type of lens attached to the camera, and b) means for controlling the drive amount of the drive means, responsive on the imaging plane displacement variable signal and the determined output signal of the focus detector. 2. Camera according to claim 1, characterized in that g e k e n n z e i c h n e t - The imaging plane adjustment variable signal generating device means for Converting the drive variable of the drive device into an electrical signal, where - this converter has a conversion factor that corresponds to that of the camera body attached taking lens is peculiar. 3. Camera according to the preamble of claim 1, g e k e n n z e i c h n e t through a) an objective-side signal generating device with - a Transfer device that determines the drive size of the drive device, this converts it into an electrical signal and emits the latter, and - a device for generating a correction signal corresponding to the type of taking lens, b) a Circuit for deriving an imaging plane adjustment variable signal from the electrical converter signal and the correction signal according to the size of the Adjustment of the imaging plane, like this from an adjustment of the taking lens originates, and c) a circuit for controlling the drive quantity of the drive device, in response to the imaging plane displacement amount signal and the output signal of the focus detector. 4. Camera according to the preamble of claim 1, g e k e n n z e i c h n e t through a) a lens-side device for generating a correction signal according to the type of the attached taking lens and b) a Converter between the focus detector and the drive device for converting the output signal of the focus detector into a drive signal for the purpose of determination the drive size of the drive device on the basis of the correction signal, wherein the drive signal has a value which represents the displacement amount of the imaging plane as a result of a lens adjustment due to the drive signal to the detected Adjusts deviation size. 5. A camera according to claim 3 or 4, characterized in that it k e n n z e i c h n e t that the correction signal is one of that in the taking lens in terms of the relationship between the drive size of the drive device and the size of the image plane adjustment has its own value as a result of lens shifting. 6. Attachable lens to a camera, provided with the camera body is with - a focus detector for with the help of passed through the lens Light taking place to determine the size of the deviation between a predetermined Focal plane and the actual imaging plane of an object, wherein the taking lens is provided with a drive device for adjustment a focusing lens system for focusing on the object in response to the Output signal of the focus detector, not shown by - a device for generating a correction signal which the taking lens with regard to the link between the drive size of the drive device and the magnitude of the imaging plane displacement as a result of a focusing lens system displacement is own.