DE4216914A1 - DEVICE FOR ADJUSTING A VARIO LENS - Google Patents

Abstract

An exposure zooming operation control device is disclosed having a power zoom lens controlled by a motor 43. An exposure value Ev is obtained based on a result of photometry, and the power zoom lens is driven in an electric mode in accordance with a program diagram proper for a zooming during an exposure. In the program diagram, the shutter speed is set between 1/15 through 1/4 second, which is slower than a usual shutter speed, but when the exposure value obtained by photometry is too large or too small, the aperture value is set to the maximum value or the minimum value, to thereby determine a proper shutter speed. <IMAGE>

Description

The invention relates to a device for adjusting of a zoom lens during exposure.

Adjusting a photographic zoom lens So far during the exposure is simultaneously with the Closure released manually. The user must have a ring on the lens as evenly as possible turn while the shutter is open.

With such a manual vario adjustment it is but difficult to get the ring in the short time of Closure opening as evenly and smoothly as possible turn so that it is correspondingly difficult to turn one to get flawless image that the adjustment of the Shows focal length during exposure.

It is an object of the invention to provide a device for Control the zoom setting during exposure  admit through which the desired image effect of the focal width adjustment during exposure without exposure is achieved.

The invention solves this problem with the features of Claim 1. Advantageous further developments are Subject of the subclaims.

A device according to the invention includes a front direction for defining a program diagram, a Device for calculating an exposure value ent speaking of a light measurement, a device for on represent the shutter speed and aperture speaking of the exposure value and the program diagram and a zoom lens that opens during the shutter opening is adjustable, this adjustment accordingly the shutter speed and aperture value is controlled. In the program diagram, the shutter speed has one for the adjustment suitable during exposure Value.

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

Fig. 1 tion the block diagram of a Kamerasteue which ren means for STEU the zoom setting during the exposure includes, for example as the execution,

Fig. 2 is a timing diagram for the operation of the camera in the Objektivverstel development during exposure,

Fig. 3 an example of a program diagram for a lens adjustment during exposure,

Fig. 4 shows the flow chart of a program Hauptpro,

Fig. 5 shows the flow chart of a selection process for a program line,

Fig. 6 shows the flowchart of a program for the adjustment during exposure and device

Fig. 7 shows another example of a program diagram for the lens adjustment during exposure.

Fig. 1 shows the control circuit of a camera in which the invention is used. This control circuit includes a microcomputer (CPU) 10 , which takes over the entire control of the camera, a microcomputer (DPU) 20 for controlling light measurement and. Ä., A microcomputer (IPU) 30 for controlling a display and a microcomputer (lens CPU) 40 for control of a photographic lens. Only the lens CPU 40 is arranged in the lens. The others are in the camera housing.

The CPU 10 carries out various types of controls, namely for automatic focusing, for calculating an exposure control, etc. For this purpose, the CPU 10 with an EE circuit 11 , a switch control 12 and motor driver circuits 13 and 14 connected ver. The EE circuit 11 generates a pulse signal, and in synchronism therewith a fade out operation is performed. The switch controller 12 is used to input a signal originating from various switches into the CPU 10 . Such switches are a light measuring switch and a trigger switch. The motor driver circuit 13 controls a motor 15 for mechanical charging. The motor driver circuit 14 controls a film transport motor 16 and a motor 17 for automatic focusing. Furthermore, the CPU 10 is connected to an E ² PROM 18 , in which information such as the number of frames of a film and various correction values are stored. It is also connected to a plurality of magnets 19 which keep the closure electrically closed or release a mirror when the closure is to be opened.

The DPU 20 is connected to a CCD device 21 , which serves as a distance measuring sensor. It is also connected to an integrated light measuring circuit 22 , which emits a voltage signal corresponding to the brightness of the object. The DPU 20 performs a light measurement operation and acts as an interface with the CCD device 21 . The DPU 20 and the CPU 10 are each connected to a display 23 which shows various information in the viewfinder of the camera and is, for example, an LED display.

The IPU 30 is equipped with a display 31 , e.g. B. an LCD display, a flash circuit 32 and a Schaltsteue tion 33 connected. The LCD display 31 is arranged on the outside of the camera and shows various information. The switching control 33 is used to select an exposure control either for program operation or for manual setting.

The lens CPU 40 is connected to the IPU 30 , which is arranged in the camera body, and receives input information for its lens from the IPU 30 . It also provides information to the IPU 30 , performing various calculations based on the information received. The lens CPU 40 is connected to a motor driver circuit 41 and a switching control 42 . The motor driver circuit 41 is used to control a zoom motor 43 , which electrically adjusts the focal length of the lens. The switching control 42 is used to select the vario drive or the manual setting as well as a mode of operation in which a vario position is to be carried out during the exposure.

Fig. 2 shows the timing diagram of the operation of the camera with vario adjustment during exposure.

This timing diagram begins by pressing the trigger button, which closes the trigger switch. As a result, the mirror is moved upwards within the camera and the aperture is set to a predetermined value. Then one of the magnets for the closing curtains is switched off and thereby the first closing curtain moves, which is shown at S 1 . If a predetermined time has passed after the movement of the first shutter curtain, the varomotor 43 is turned on at A. Then the other magnet for the closure is switched off, whereby the second closing curtain is moved at S 2 . At the same time, the vario motor 43 is stopped. The rotation of the zoom motor 43 is thus started approximately in the middle of a period in which the exposure takes place, so that there is a zoom adjustment during the exposure. The vario adjustment takes place in the second half of the exposure time.

Fig. 3 shows a program diagram for a Varioein setting during the exposure.

According to this diagram, a picture is taken with an exposure time of 1/15 second (see P 1 ) which is longer than a usual exposure time. It results from test recordings and is a limit value for which the effect of a zoom setting during exposure can be fully recognized in the image. A shutter speed longer than 1/15 second is favorable, so that, for example, a range between 1/15 and 1/4 second is suitable for a vario setting during exposure.

However, a picture cannot always be taken with an exposure time of 1/15 second. If an exposure value Ev is calculated in accordance with a light measurement and is greater than 13, ie too large, the aperture value Av is set to 22 as the upper limit or maximum value (see P 2 ). The recording is then carried out with a shutter speed corresponding to the maximum aperture value. On the other hand, if the exposure value after light measurement is less than 5, i.e. too small, the aperture value is set to 1.4 as the lower limit or minimum value (see P 3 ), and the picture is taken with a shutter speed corresponding to this minimum value.

Thus, the diagram shown in FIG. 3 contains a line for constant aperture value corresponding to a maximum and a minimum. If the exposure value is between 5 and 13, a zoom adjustment is carried out during the exposure at a constant shutter speed of 1/15 second and the aperture value is changed accordingly.

The operation of such a device is explained below using the flow diagrams in FIGS . 4 to 6.

Fig. 4 shows the flowchart of a main program. The ports of the CPU 10 are initialized in step 101 , and an automatic exposure (AE) is initialized in step 102 , ie correction data for a calculation of the exposure control are read from the E ² PROM 18 . Then, in step 103, data for automatic focus control (AF) is read from the E ² PROM 18 .

In step 104 , the states of various switches, for example the light measuring switch and the release switch, are read from the switch control 12 . When AF operation is set, auto focus is performed using the AF control on the lens.

In step 106 it is checked whether 4 milliseconds have elapsed after a predetermined time. When this time is reached, the control goes from step 106 to step 107 , where it is checked whether the trigger switch is closed. So the state of the trigger switch is checked every 4 milliseconds, and when it is closed, the shutter is triggered. If it is determined in step 106 that the time of 4 milliseconds has not yet been reached, then in step 110 it is checked whether 100 milliseconds have expired after a predetermined point in time. If this is not the case, steps 104 and 105 are carried out. After reaching 100 milliseconds, steps 111 to 113 are carried out.

In step 111 , predetermined data is transferred from the IPU 30 to the CPU 10 . This data includes, for example, information about the type of exposure and information about whether the zoom lens is switched to electrical or manual mode. A light measurement is carried out in step 112 , an exposure value Ev being calculated from photometric data. In addition, processes for a P-line selection ( FIG. 5) and an EXZP routine ( FIG. 6) are carried out, which will be described later. In step 113, the data for the display 31 is transferred from the CPU 10 to the IPU 30 , and control then returns to step 104 .

Fig. 5 shows the flowchart for the selection of a program line (P line).

If it is determined in step 121 that the program mode is not set, the routine is ended immediately. If the program mode is set, control goes to step 122 , where it is checked whether an electrically drivable zoom lens is attached to the camera housing. In step 123 it is checked whether the zoom lens is switched to electrical operation. In step 124 , it is checked whether the zoom setting is set during the exposure (EXZOOM mode). If a zoom lens with electric drive is present, the electric drive and EXZOOM operation are set and control goes to step 125 , where a flag is set for execution of the zoom adjustment program during exposure. If one of the conditions of steps 121 to 124 is not met, the routine is ended without executing step 125 .

Fig. 6 shows the flow chart of a program for the vario adjustment during exposure. LvD corresponds to an exposure value Ev obtained from photometric data. TvD corresponds to the exposure time and AvD corresponds to an aperture value. The values LvD, TvD and AvD fulfill the relationship LvD = TvD + AvD. LvD is a calculation value for the exposure value, TvD a calculation value for the shutter speed value and AvD a calculation value for the aperture value. LvD is determined from the light measurement data, and then TvD and AvD are determined, for example, according to the program diagram shown in FIG. 3.

In step 131 , TvD is set as the shutter speed for the vario setting during an exposure as EXZTVD (time value Tv, for example, corresponding to 1/15 second). In step 132 , TvD is subtracted from LvD to obtain AvD.

It is then checked in step 133 whether AvD is greater than Av-DMAX. If so, control transfers to step 134 where AvD is replaced with AvDMAX. If it is determined in step 135 that AvD is less than AvDMIN, control transfers to step 136 where AvD is replaced by AvDMIN. If it is determined in steps 133 and 135 that AvD lies between AvDMAX and AvDMIN, this routine is ended immediately.

If AvDMAX or Av-DMIN is replaced in step 134 or 136 , step 141 is carried out, where AvD is subtracted from LvD to obtain TvD.

Then, if it is determined in step 142 that TvD is greater than TvDMAX, control goes to step 143 where TvD is replaced by TvDMAX. If it is determined in step 144 that TvD is less than TvDMIN, control transfers to step 145 where TvD is replaced by TvDMIN. If it is found in steps 142 and 144 that TvD lies between TvDMAX and TvDMIN, this routine is ended immediately.

Thus, TvD and AvD are determined according to the program diagram shown in FIG. 3.

As described above, the vario adjustment performed during the exposure such that the loading glade time usually on z. B. 1/15 second and the zoom lens during opening hours the closure is electrically driven. The The opening time of the shutter is reduced to one Vario setting suitable value during exposure or a value as close as possible to this set and then the vario setting with electri executed. This creates an image that the effect of the focal length change during the loading clearing can be seen.

Although the line P 1 for the exposure time in the program diagram shown in FIG. 3 is fixed at 1/15 second, it can also be inclined according to FIG. 7, so that the exposure time changes with the aperture value.

Claims (8)

1. A device for controlling the focal length change of a zoom lens for a camera during the exposure, with a device for defining a program diagram, a device for calculating an exposure value in accordance with the result of a light measurement, and a device for setting the exposure time and the aperture value in accordance with the Exposure value and the program diagram, characterized in that the zoom lens is adjusted during the opening time of the shutter under control by the opening time and the aperture value. 2. Device according to claim 1, characterized net that the program diagram corresponds to a line contains a constant exposure time. 3. Device according to claim 2, characterized net that the constant exposure time 1/15 to Is 1/4 second. 4. Device according to one of the preceding claims che, characterized in that the program slide gram a line corresponding to a change in Exposure time depends on the aperture value holds. 5. Device according to claim 2, 3 or 4, characterized ge indicates that the program diagram is also a Line corresponding to a constant aperture value contains that corresponds to the maximum aperture value.   6. Device according to claim 5, characterized net that the device for adjusting the loading clearing time sets a maximum value if the Belich obtained from the program diagram time is longer than the maximum value. 7. Device according to one of claims 2 to 6, there characterized by that the program diagram also a line for a constant aperture value contains that corresponds to the minimum aperture value. 8. Device according to claim 7, characterized net that the device for adjusting the loading clearing time sets a minimum value if the Belich obtained from the program diagram time is less than the minimum value.