DE19655198C2 - A distance - Google Patents

Abstract

The invention relates to a distance measuring device for a camera, which can be set to a macro range for close-up pictures. The distance measuring device has lens sensors, which each consist of a plurality of light receiving elements and on each of which an object image is generated. The distance measuring device furthermore contains a memory which stores predetermined correction data which, for each line sensor, indicate the amount of the deviation between a first group of light-receiving elements on which the object image falls during normal exposure and a second group of light-receiving elements on which the object image falls upon close-up. Furthermore, the distance measuring device contains a device for selecting a group of light receiving elements in accordance with the predetermined correction data in order to derive electrical signals only from these recording elements, and a device for calculating a distance value using image data derived from the electrical signals.

Description

The invention relates to a passive distance measuring device device that works using external light and z. B. is applicable in a camera.

Some central locking cameras have an auto focus system a passive distance measurement. This contains Abbil lens as an optical system and two line sensors each of which an object image is generated, around the object to calculate distance with triangular calculation. In these cameras are the lens, the viewfinder system and the optical distance voltage measurement system independent of each other. In some cameras this type is the distance measuring device as a single ne unit executed, d. H. it consists of the two figures application lenses, two line sensors each with a large an number of light receiving elements (i.e., photodiodes) on which several Images of an object are projected, and an arithmetic unit for calculating the distance according to the data output by the line sensors. At the distance measuring unit  falls the optical axis of the optical Ent distance measuring system not with the optical axis of the recording mesystems or the viewfinder system together.  

Furthermore occurs in previous cameras in which the optical Axis of the distance measuring system of the distance measuring unit not with the optical axis of the recording system or the optical viewfinder system matches, in a macro for close-ups and when the optical deviation is large  Axis of the distance measuring unit from that of the recording systems to the left or right side of the camera a sub the position of a light-receiving area of the line sensors on which the object forms during normal recording pro be jected, where the removal of one on the opti rule arranged object above a predetermined Value, and the corresponding position in close-up on where one is within a certain distance range measured distance is small. The AF frame in the viewfinder image and the light absorption area of the respective line sensor do not correspond to each other in macro photography, so the object distance cannot be measured exactly.

The problem of being in a camera with distance measuring device Parallax occurring is addressed in DE 40 14 887 A1 chen. There a distance measuring device is described whose optical axis is not the same as the optical axis of the came rasuchers and the optical axis of the camera lens together menfällt. The optical axis of the camera viewfinder is there pivotable to face the parallax of the camera lens to reduce the camera viewfinder in macro photography. To the associated displacement of the distance measuring zone in to compensate for the viewfinder field are also for the normalfo topography determined line sensors further line sensors provided that are used in macro photography.

The object of the invention is a Ent distance measuring device for a camera to specify with the egg ne object distance can be measured precisely even with macro shots, if the optical axis of the distance measuring unit differs from that the lens by a large amount to the left or right side of the camera deviates.

The invention solves this problem by the features of claim 1. An advantageous further development is specified in claim 2.  

The invention is a accurate distance measurement possible, even if parallax between the distance measuring unit and the taking lens in macro shooting exists because the first and the second Group of light receiving elements optionally for normal exposure and can be used for close up.  

The invention will now be described with reference to the drawings explained. In it show:

Fig. 1 is a front view of a camera with a nungsmeßvorrichtung Entfer,

Fig. 2 is a rear view of the camera shown in Fig. 1,

Fig. 3 is a plan view of the camera shown in Fig. 1,

Fig. 4 is a block diagram of the control system of the camera shown in Fig. 1,

Fig. 5 is a schematic representation of the internal structure of a distance measuring unit of the GE in Fig. 1 showed camera,

Fig. 6, the general method for measuring distance with two line sensors using the triangle bill,

Fig. 7 is a schematic diagram of a distance measuring unit as shown in Fig. 1 to 3 shown ra,

Fig. 8 is a schematic representation of the light receiving areas of a line sensor in the distance measurement unit of FIG. 7,

Fig. 9 is a schematic representation of variations of the positions of the light receiving regions by changing the focal length,

Fig. 10 AF frame in the finder field of view of a camera,

Fig. 11, 12 and 13 are flowcharts of the main routine of a camera with a distance measuring device,

FIGS. 14 and 15 are flow charts of a recording subroutine in a camera having a distance measuring device,

FIGS. 16 and 17 are flow charts of a multi-AF operation in a camera having a distance measuring device

Fig. 18 AF frame in the finder field of view of a camera with a distance measuring device,

Fig. 19 is a schematic representation of a deviation of the optical axis of the ranging unit in a camera having a distance measuring device,

Fig. 20, the diagram of the output data nungsmeßeinheit a Entfer when its optical axis is deviated from a reference axis in the camera of Fig. 19,

Fig. 21 is a line sensor with additional Lichtaufnah meelementen corresponding to a maximum Pa rallaxeneinstellbetrag in the camera of Fig. 19,

Fig. 22 is the flowchart of a pickup operation in egg ner camera with a distance measuring device,

Figure 23 is a flow chart of a distance measurement processing. In a camera having a Entfernungsmeßvorrich,

Fig. 24 is the flowchart of a multi-AF operation in egg ner camera with a distance measuring device,

Fig. 25 is the flowchart showing a spot AF operation in egg ner camera with a distance measuring

Fig. 26 is a schematic representation of a deviation of the optical axis of a distance measuring unit according to the invention, in Ma krobetrieb the camera,

Fig. 27 shows the chart of output data of a Entfer nungsmeßeinheit at normal recording and Ma kroaufnahme with the camera of Fig. 26,

Fig. 28 is a view of light receiving areas in macro mode of the camera of Fig. 26,

Fig. 29 shows the flowchart of a pickup operation with egg ner camera with the distance measuring accelerator as the invention,

Fig. 30, the flow chart of a distance measurement operation in a camera having a Entfernungsmeßvorrich processing according to the invention, and

Fig. 31 is a flow chart of a macro AF operation in a camera with a distance measuring device according to the invention.

A camera with a distance measuring device is described below with reference to FIGS . 1 to 17. It is a camera 11 with a lens shutter and a distance measuring unit. In the camera 11 , the optical axis of the optical system of the distance measuring unit 18 does not coincide with the optical axis of the lens or the optical axis of the viewfinder system. This camera will be referred to later in the description of an embodiment of the invention.

As Fig. 1 shows, the camera 11 has at its front side an electrically-driven zoom lens 13, a ferngesteu Erten light receiving part 14, a lamp 10 for displaying the self-timer mode, a light-receiving window 15, an AF auxiliary light source 16, a viewfinder objective window 17, a light receiving window 18 'and a flash unit 19 . Two AF lenses 25 and 26 of the passive AF unit 18 are arranged behind the light receiving window 18 '.

As shown in Fig. 2, the camera has a rear cherokular window 24 , a main switch 65 , a zoom switch 21 and a rear wall 22 to be opened on its back. The vario switch 21 can be operated in the telephoto direction T or in the wide-angle direction W, whereby the lens 13 is moved to the focal length change in the respective direction.

As shown in FIG. 3, the camera 11 has a release button 20 and an external LCD 23 on its upper side for displaying various photographic information. A flash switch 40 , an operation mode selector switch 41 , a date switch 42 , a spot AF selector switch 43 and a shooting mode switch 45 are arranged around the external LCD 23 . A macro switch 46 is located behind the release button 20 . The date switch 42 is used for setting the date, changing the shape of the date display in the external LCD 23, and changing the date exposure pattern on a film. The date change state can be selected by continuously pressing the date switch 42 for a time of 3 seconds. By pressing the recording mode switch 45 , the shutter actuation can be changed between a single image recording, a series image recording, a self-timer recording, a B recording, etc.

The control system of the camera 11 is described below with reference to FIG. 4.

The camera 11 includes a CPU 50 for controlling the various shooting operations. The CPU 50 starts controlling each operation according to a predetermined program in an internal memory of the CPU 50 .

A varomotor drive circuit 53 , a film feed motor drive circuit 54, and a lamp drive circuit 55 are connected to the CPU 50 . The variomotor driver circuit 53 controls a variomotor 51 for the lens 13 . The film transport motor driver circuit 54 controls a film transport motor 52 for transporting and rewinding a film. The lamp driver circuit 55 controls a red lamp 12 a, a green lamp 12 b and the self-timer lamp 10 so that they are on or off or blink. The red and green lamps 12 a and 12 b are arranged next to a viewfinder field 47 ( Fig. 10) in the viewfinder, so that their red and green light can be seen through the viewfinder. The red lamp 12 a indicates whether a flash is available or not, while the green lamp 12 b indicates whether an object is in focus or not.

The external LCD 23 , a viewfinder LCD 57 , a flash circuit 58 for the flash device 19 , the distance measuring unit 18 , the AF auxiliary light source 16 , a light measuring circuit 62 and a temperature detection circuit 63 are connected to the CPU 50 .

The viewfinder LCD 57 is arranged in the viewfinder and represents a plurality of focusing frames Fa, Fb, Fc and Fd in the viewfinder image field 47. The light measurement circuit 62 calculates a light measurement value accordingly with a light receiver, ie a CdS cell (cadmium sulfide cell) data is arranged behind the light-receiving window 15 . The temperature detection circuit 63 detects the ambient temperature of the camera 11 by signals from a thermal sensor such. B. a thermistor.

A backplane switch 64 , the main switch 65 , a teleschal ter 66 , a wide-angle switch 67 , a panorama switch 68 , the flash switch 40 , the mode selector switch 41 , the date switch 42 , the spot AF selector switch 43 , the recording type switch 45 , a light measuring switch 74 , a trigger switch 75 and the macro switch 46 are connected to the CPU 50 .

The mode selector switch 41 serves to select one of a plurality of predetermined exposure types. These include multi-AF shooting and spot AF shooting. The selector switch 41 can also choose a flash lock. The light measuring switch 74 is turned on when the release button 20 is pressed halfway, while the release switch 75 is turned on when the release button 20 is fully pressed.

A DX code reading circuit 77 , a lens information reading circuit 78 , a date LED driver circuit 79 , a film motion detection circuit 81 , an EEPROM 82 , a RAM 83 and a ROM 84 are connected to the CPU 50 . The DX code reading circuit 77 reads ISO film sensitivity information from a film cartridge via DX code contact springs (not shown). The lens information reading circuit 78 reads rio information of the lens 13 . The date LED driver circuit 79 operates a 7-segment digital display 80 to expose date or time information corresponding to the operation of the date switch 42 .

As Fig. 5 shows, the distance measuring unit 18 has two Ab formation lenses (ie, image formation system) 25 and 26 and two line sensors 27 and 28. The imaging lenses 25 and 26 are arranged so that they have a distance equal to the base length to each other. Images of an object are generated on the line sensors 27 and 28 via the imaging lenses 25 and 26 , respectively. The line sensors 27 and 28 have the same shape and each have a plurality of light receiving elements (photodiodes) which are aligned in the left and right directions of the camera 11 , so that they cover the maximum field angle of the lens 13 . The signals read by the line sensors 27 and 28 are represented as small signal groups. These signal groups each correspond to small groups of light-receiving areas on the line sensors 27 and 28 , which take object images at different field angles.

A general method for measuring an object distance with two line sensors 27 'and 28 ' based on the triangular calculation is explained below with reference to FIG. 6.

In Fig. 6, f is the focal length of the imaging lenses 25 'and 26 ' OA ₁ and OA ₂ are the optical axes of the imaging lenses 25 'and 26 '. They are parallel and have a distance B from one another B. At points b ₁ and b ₂ , the optical axes OA ₁ and OA ₂ meet the line sensors 27 'and 28 '. The distance between these two points is therefore the base length, which corresponds to the distance B. An object P has the distance Lx to the imaging lenses 25 'and 26 '. The object P is viewed here in a punctiform manner. It is assumed that images of the object P with the distance Lx are generated at the points X ₁ and X ₂ on the line sensors 27 'and 28 ' with the imaging lenses 25 'and 26 ', and that the distance between the pixels X ₁ and X _{2 has} the length x. Furthermore, the distance XL is formed between the points b ₁ and X ₁ and the distance XR between the points b ₂ and X ₂ . This results in the following relationship:

B: (XL + XR) = Lx: f

The distance Lx is given by

Lx = Bf: (XL + XR)

Lx = B.f: (x - B)

In the exemplary embodiment shown, the focal length f of the imaging lenses 25 'and 26 ' and the distance between them, ie the base length B, have fixed values. The distance Lx is therefore obtained by calculating the distances XL and XR or the distance x. In this example, the points X ₁ and X _{2 are} detected to derive the distance x and, hence, the distance Lx.

In general, an object to be recorded is not just a point, which is why the object images generated on the line sensors 27 'and 28 ' are two-dimensional. Therefore, the pixels X ₁ and X ₂ cannot be detected directly.

For this purpose, a predetermined number of light-receiving elements (for example one or two elements) of the line sensor 27 'is compared with the same number of light-receiving elements of the line sensor 28 '. This comparison is repeated with a relative change in the light-receiving elements to be compared with one another. If one obtains the highest degree of coincidence of the light distributions on the line sensors 27 'and 28 ', the distance between the light receiving elements is defined as the image distance x.

A plurality of light receiving areas are correspondingly defined on each line sensor 27 and 28 . Each light receiving area contains a predetermined number of light receiving elements.

The CPU 50 shifts or changes the light receiving areas to be used on each line sensor 27 , 28 in accordance with data indicating the focal length area information read from the RAM 83 . This focal length range information is stored in the RAM 83 when the focal length is changed, and results from the lens information read by the information reading circuit 78 . Four predetermined position groups a, b, c and d are stored in the ROM 84 , as shown in FIG. 9.

Each line sensor 27 , 28 contains at least 128 light receiving elements arranged side by side. As shown in FIG. 8, each line sensor has five light receiving areas, namely a central area C (first light receiving area), a light receiving area LC (second light receiving area), an area RC (third light receiving area), a left area L (fourth light receiving area) and one right area R (fifth light receiving area). Each of the five light receiving areas C, LC, RC, L and R contains 36 light receiving elements. The light receiving area LC overlaps the right part of the left light receiving area L with 13 light receiving elements and the left part of the middle light receiving area C with 13 light receiving elements. Similarly, the light receiving area RC overlaps the right part of the middle light receiving area C with 13 light receiving elements, and the left part of the right light receiving area R with 13 light receiving elements.

The reason for such a structure in which two adjacent light receiving areas overlap each other by a predetermined amount is that the distance information is not available if the contrasts of an object occur only at the boundaries between light receiving areas, because the contrast then occurs in both light receiving areas is not recorded. As shown in FIG. 7, the light absorption areas C, L, R, LC and RC correspond to the object light sections areas C ', L', R ', LC' and RC '. In practice, each line sensor 27 , 28 consists of more than 128 light receiving elements, so that each left and right edge of the line sensor can have an edge.

The method for distance measurement by selectively using the light receiving areas C, L, R, LC and RC of the two line sensors 27 and 28 is referred to below as a multi-AF method.

The method for measuring the object distance by optionally using the light receiving areas C, LC and RC of the two line sensors 27 and 28 is referred to below as the spot AF method.

Multiple images of a common object are generated on each line sensor 27 and 28 in different areas via the imaging lenses 25 and 26 . The amount of light received with each line sensor 27 , 28 , which leads to a respective stored electrical charge, is converted into electrical signals, and these electrical signals are the CPU 50 via a corresponding quantizer 29 , 30 and an arithmetic operation part 31 in the distance measurement Unit 18 fed.

A comparator and a holding circuit are provided in the quantizing part 29 or 30 and are connected to each light receiving element. The electrical charge accumulated in this is quantized via the comparator and the holding circuit. The quantized data of each line sensor 27 , 28 who serial to the CPU 50 via the arithmetic operations part 31 . From all of the sensor data obtained from all the light-recording elements of each line sensor 27 , 28 , the CPU 50 can select only a part of the data of each line sensor 27 , 28 and can use only this selected sensor data for a distance measurement.

If the multi-AF mode is selected with the mode selector switch 41 , the CPU 50 selects one of the four position patterns a, b, c, d ( FIG. 9) in accordance with the focal range information of the lens 13 , which is stored in the RAM 83 is rich in association with the position data of the light-receiving areas read from the ROM 84 . The CPU 50 then receives the signal groups of the selected position pattern from the arithmetic operation part 31 and calculates a distance from the signals, which results in an adjustment of the focusing lens. This is an exposure / focus driver circuit 59 supplied to adjust the focus lens accordingly.

If the multi-AF mode is selected with the mode selector switch 41 , the focal length change range (Variobe range) of the lens 13 is divided into four sections from the wide angle limit position to the telephoto limit position. The control of the camera changes the positions of the light receiving areas L, R, LC and RC relative to the position of the central light receiving area C in the manner shown in FIG. 9 in accordance with a variation of the focal length. The CPU 50 selects one of the predetermined position patterns of the light receiving areas of each line sensor 27 , 28 , that is, the position pattern a, b, c or d corresponding to the data of the focal length area information from the RAM 83 when the focal length is changed. Although the positions of the light receiving areas L, R, LC and RC are shifted relative to the position of the central light receiving area C when a position pattern a, b, c or d is changed to another pattern, each light receiving area always consists of 36 light receiving elements ,

As shown in FIG. 10, the viewfinder LCD 57 of the camera 11 has four AF frames Fa, Fb, Fc and Fd each of different sizes, which correspond to the position patterns a, b, c and d in FIG. 9. The four AF frames can be seen in the viewfinder image field 47 . Each AF frame (ie measuring zone) consists of a left and a right bracket-like LCD segment. Only the AF frame Fa is activated, ie visible when the position pattern a is selected, ie the lens 13 is in the wide-angle limit position. Similarly, only the AF frame Fd is activated, ie visible when the position pattern d is selected, ie the lens 13 is in the telephoto limit position. If the focal length is changed from the wide-angle limit position to the Te le limit position, the effective position pattern changes from a to d, and the activated AF frame is shifted from Fa to Fd. Accordingly, the AF frame or the measuring zone in the camera 11 is wide at the telephoto limit position and narrow at the wide-angle limit position corresponding to a change in the focal length of the lens 13 . With this construction, the large difference between the current light receiving area and the AF frame is almost completely reduced, and the user can thus visually check the current size of the light receiving area at a focal length that has just been selected.

The operation of the camera with the circuit described above is explained below with reference to the flow diagrams shown in FIGS . 11 to 17. It is controlled by the CPU 50 in accordance with predetermined programs in the ROM 84 .

When the main switch 65 is turned on to feed each circuit, control enters the main routine shown in FIG. 11. In this main routine, switch information such as ON / OFF status information is input to the main CPU 50 from each of the switches connected to it, such as the light measuring switch 74 , at step S1. Thereafter, the ON / OFF state of the rear panel switch 64 is checked at step S2. If it is in the OFF state, it is determined that the rear wall 22 is closed, and control goes to step S3. If the rear wall switch 64 is in the ON state, it is determined that the rear wall 22 is open, and control goes to step S4. At step S4, it is checked whether a film loading operation is completed. Control goes to step S3 when it is determined that the film loading operation is completed.

If this is not the case, the control goes to a sub "Load" routine at step S5 to load the film.

In step S3, it is checked whether the lens 13 is in the retracted rest position, for which purpose the zoom information from the reading circuit 78 is used. Control proceeds to step S7 if it is determined that the lens 13 is in the retracted position or to step S6 if it is not. At step S7, it is checked whether the main switch 65 is in the ON state. If this is the case, the control goes to a subroutine "extend lens" in step S8, in which the lens 13 is moved from its retracted position by a small amount to an initial position which is the wide-angle limit position. If the main switch 65 is not in the ON state in step S7, the control goes into a subroutine "switch off supply" in step S9.

At step S6, it is checked whether the main switch 65 has been brought into the ON state. If so, it is determined that the camera 11 has just been activated, and control goes to step S11 to stop the date change operation if it is in effect, and the newly entered date is displayed on the external LCD 23 . At step S11, the previously set date is displayed on the external LCD 23 when the date changing operation is not effective. Thereafter, control goes to a lens retract subroutine at step S12. If it is determined in step S6 that the main switch 65 has not been brought into the ON state, the control goes to step S10 to check the state of the tele switch 66 . If it is determined in step S10 that the teleswitch 66 is in the ON state, it is checked in step S14 whether the date change operation is effective. If it is determined in step S10 that the tele switch 66 is not actuated, control goes to step S13.

If it is determined in step S14 that the date change operation is not effective, control goes to step S15 to check whether the lens 13 is in its telephoto limit position. If it is determined in step S14 that the date change operation is in effect, the control goes to a subroutine "adding setting" in step S16. This subroutine is used to set the date or time on the external LCD 23 in the date change mode by increasing the day, month, year, hour or minute. This respective size is selected in a subroutine "shift position ver" at step S52 for setting ( Fig. 13).

If it is determined in step S15 that the lens 13 has its telephoto limit position, control goes to step S13 to check whether the wide-angle switch 67 is operated. If the lens 13 is not in the telephoto limit position in step S15, the control goes to step S17 to check whether the lens 13 is in the macro position, in accordance with the vario information provided with the lens information reading circuit 78 ,

If it is determined in step S17 that the lens 13 is in its macro position, the control goes to a subroutine "drive to telephoto limit" in step S19 in order to bring the lens 13 from the macro position to the telephoto limit position. If the lens is not in its macro position at step S17, the control goes to a subroutine "focal length towards telephoto limit" at step S18 to move the lens 13 from the current position towards the telephoto limit position.

If it is determined in step S13 that the wide angle switch 67 is in the ON state, control goes to step S20 to check whether the date change operation is in effect, or to step S26 if the wide angle switch 67 is in the OFF state.

If it is determined in step S20 that the date change operation is in effect, control goes to a subroutine "subtracting setting" in step S22. If the date change operation is not effective, it is checked in step S21 whether the lens 13 is in the wide-angle limit position. The subtracting setting subroutine at step S22 serves to set the date or time on the external LCD 23 in the date changing operation by decreasing the number of the day, month, year, hour or minute. This respective position is selected in the subroutine "shift setting position" at step S52.

If it is determined in step S21 that the lens 13 has its wide-angle limit position, control goes to step S26 or, if it does not have this position, to step S23.

In step S23 it is checked whether the lens 13 is in its macro position. If this is the case, control goes to a subroutine "drive to telephoto limit" in step S25 in order to bring the lens 13 from the macro position to the telephoto limit position. If the lens 13 is not in its macro position at step S23, control goes to a subroutine "focal length toward WW limit" at step S24 to move the lens 13 from the current position to the wide-angle limit position.

At step S26 ( FIG. 12), it is checked whether the macro switch 46 is in the ON state. If this is the case, control goes to step S28 to check whether the lens 13 is in the macro position or to step S27 if the macro switch 46 is in the OFF state.

If it is determined in step S28 that the lens 13 is in the macro position, control goes to step S27. If the lens 13 is not in the macro position, control goes to a subroutine "drive for macro position" in step S29.

At step S27, it is checked whether the shooting mode switch 45 has been turned ON, and control goes to step S31 if it is, or step S30 if it is not.

It is determined at step S31 that the date change date drive is effective, control returns to step S1 back. If this is not the case, the control goes to one Subroutine "set recording mode" at step S32.

After completion of the "set recording type" subroutine, control goes to step S33 to check whether the recording type switch 45 is ON or OFF. Control returns to step S1 if it is in the OFF state. If it is determined that it is in the ON state, a timer is started in the CPU 50 and control goes to step S34. The timer continues to count while the recording mode switch 45 is pressed, ie it maintains its ON state, but is reset when the recording mode switch 45 comes to the OFF state.

At step S34, it is checked whether three seconds have elapsed since the start of the timer. If so, control goes to step S35 to check whether the trigger switch 75 is in the ON state. If these three seconds have not expired, control goes back to step S33.

If it is determined in step S35 that the release switch 75 is in the ON state, control goes to a "drive to wide angle limit" subroutine in step S36, and then to a "rewind" subroutine in step S37 to rewind the film. Thereafter, control returns to step S1. If it is determined in step S35 that the release switch 75 is in the OFF state, control returns to step S33.

At step S30, it is checked whether the mode selector switch 41 has been turned ON and control goes to step S38 if it is. It goes to step S40 if it does not have this state.

At step S38, it is checked whether the date change operation is effective or not, and control returns to step S1 if the date change operation is effective. It goes to a "set mode" subroutine at step S39 when the date change operation is not effective. In the subroutine "Set operating mode", the operating mode Spot AF or Multi AF can be set as the distance measuring mode. At step S40 ( Fig. 13), it is checked whether the flash switch 40 has been turned ON. Control goes to step S42 if it is, or step S41 if it is not.

At step S42, it is checked whether the date change operation is in effect. If so, control returns to step S1, otherwise it proceeds to step S43. At step S43, it is checked whether the flash lock is set with the mode selector switch 41 and is effective. If it is, control goes to step S44, otherwise to step S1.

In step S44, any pre-flash is turned on (Red-eye reduction mode) temporarily switched off, weh The lightning lock is effective. After extinguishing the flash the pre-flash is activated again.

At step S41, a check is made to see if the date switch 42 has been turned ON, and control goes to step S46 if it is, otherwise to step S45.

If the external LCD 23 displays the date in the date change mode, for example "95 2 3" (ie February 3, 1995), a flashing of one of these numbers indicates that this number is currently adjustable. The flashing number can be increased by operating the zoom switch 21 in the direction of Tele T (ie to the right) or decreased in the direction of wide angle W (ie to the left). With each actuation of the data switch 42 (or when it comes to the ON state), the currently flashing number is switched to the next position to the right in the order 95 , 2 , 3 , 95 , 2 , 3 etc.

At step S46, it is checked whether the date change operation is in effect. If this is the case, control goes to a subroutine "shift setting position" at step S52, the number flashing on the external LCD 23 being shifted to the next position to the right. Control then returns to step S1 after step S52 is completed.

If the date change operation is not effective at step S46, control goes to step S47 to change the previously selected form of date display on the external LCD 23 . It should be noted here that there are different types of date display. For example, suppose the date is February 3, 1996, and the time is 9:00 and 25 minutes in the morning. This information can be displayed on the external LCD 23 in one of the following five forms: 1. Form: 2 3 96 (ie month, day, year); 2nd form: 3 2 96 (ie day, month, year); 3rd form: 96 2 3 (ie year, month, day); 4th form: 3 09:25 (ie day, hour, minute); 5. Form: - - - (ie no date information is exposed). If the date change mode is not effective, the previously selected date display is changed to another each time the date switch 42 is actuated.

After step S47, control goes to a subroutine "Date display" at step S48 to display the current date information tion in the chosen form.

When step S47 is completed, control goes to step S49 to check the state of the date switch 42 . Control returns to step S1 when the date switch 42 is in the OFF state. If it is ON, a timer starts in the CPU 50 , and control goes to step S50. The timer continues to count while the data switch 42 is pressed, ie it maintains its ON state and is reset when the date switch 42 comes to the OFF position.

At step S50, it is checked whether three seconds have elapsed after the timer started. If this is the case, control goes to step S51 to enter the date change mode, in which one of the above-mentioned forms of representation is displayed on the LCD 23 , for example the third form 96 2 3. Since three seconds have expired, flashes the first number at the left end of the date shown, that is the number 96 . Thereafter, control returns to step S1. If the three seconds have not yet elapsed, control returns to step S49.

At step S45, it is checked whether the light measuring switch 54 has been turned ON, and the control proceeds to step S54 if it is. Otherwise, it goes to step S53.

At step S54, a check is made to see if a film loading error has been detected, and control goes to step S53 if it is. If no error is detected, it goes to step S55 to check the completion of the rewind. Control transfers to step S53 if the rewind end is determined in step S55, or to a record subroutine ( Figs. 14 and 15) if rewinding is not completed in step S56. After the subroutine "recording" is finished, control goes to step S53.

At step S53, it is checked whether flash charging is required and the controller goes to a sub-routine "lightning charge" at step S58 if the charge is necessary or to one Subroutine "shutdown operation" at step S57 to save solution of the camera.

Fig. 14 and 15, the subroutine "recording" show at step S56. In this subroutine, the ISO film sensitivity printed on the inserted film cartridge is first read through the DX code reading circuit 77 at step S60. Thereafter, the capacity of the battery is checked in step S61. At step S62, a check is made to see if an error has been detected at step S60 or step S61, and control returns if there is an error or goes to a subroutine "Multi-AF" at step S63 if no error has occurred. After the completion of step S63, a predetermined light measurement calculation is carried out with the light measurement circuit 62 at step S64, and thereafter a predetermined AE calculation is carried out at step S65.

At step S67, it is checked whether a ver reversible distance value has been calculated (i.e. checks whether there is any error in the distance calculation ten), and control goes to step S71 if on for the usable distance value is not calculated has been. It goes to step S68 when it is determined that calculates the distance value that can be used for the recording is (i.e. there is a calculated distance value).

In step S71, the green light is flashing b tet is stale 12, to inform the user that a Focus Stel development is not possible. At step S68, it is checked whether the subject to be photographed is too close to the camera 11 to enable focusing, and control goes to step S71 if it is. If not, go to step S69. At step S69, the green lamp 12 is b permanently switched to the user to precise information ren that the object to be recorded is now in focus.

At step S70, it is checked whether a flash is required, and control goes to step S72 if it is, otherwise, it goes to step S76. In step S72, an FM (Flashmatic) calculation is carried out, and then in step S73 it is checked whether the flash capacitor is fully charged. Control goes to step S75 if the flash capacitor is fully charged or step S74 if it is not. At step S75, the red lamp 12 is a permanently switched to the user to precise information ren that the flash is ready to fire. At step S74, the red lamp 12 is a flashing switched to the user to form in that the flash is not yet ignited.

Step S76 is a "switch information input" subroutine in which the CPU 50 inputs the information of each switch. After step S76, control goes to step S77 to check the state of the trigger switch 75 , and then goes to step S78 if the trigger switch is ON or to step S79 if it is OFF.

At step S79, the state of the light measuring switch 74 is checked, and control returns to step S76 if it is in the ON state or to step S80 if it is in the OFF state. In step S80, the red lamp 12 a or the green lamp 12 b is switched off.

At step S78, it is checked whether the self-timer operation has been set with the shooting mode switch 45 , and control goes to a subroutine "Wait" at step S81 if this operation has been set, or returns if it is not. The "wait" subroutine is used to release the shutter only when a predetermined time (for example, seven seconds) has elapsed after the release button 20 has been completely depressed. After step S81, control goes to step S82 to check whether the self-timer operation has been interrupted, and control returns if it is. Otherwise, go to step S83.

In step S83 ( FIG. 15), the self-timer lamp 10 is switched on, and the green lamp 12 b and / or the red lamp 12 a is switched off. Thereafter, the focusing lens of the lens 13 is moved to focus at step S84, after which the lamp 10 is turned off at step S85. The shutter is then released at step S86, and after the end of exposure, the film is advanced by one frame at step S87.

After step S87, it is checked in step S88 whether the automa table rewinding is effective, and control goes to Step S89, if so, so that the film returns is spooled. Otherwise the control goes back. The au Tomatical rewinding can optionally be done by pressing one (Not shown) rewind button set or reset be provided on the camera body. The automatic Rewind starts immediately after the last one is exposed Image field on the film.

FIGS. 16 and 17, the subroutine "Multi-AF" show the step S63.

Four sensor start numbers, ie DIV0, DIV1, DIV2 and DIV3, each corresponding to the first, second, third and fourth section of the zoom area of the lens 13 , determine the position of each light receiving area C, L, R, LC and RC and are in the RAM 83 is stored in accordance with the information available with the lens information reading circuit 78 when the focal length is changed or the macro mode is turned on, in accordance with the operation at step S10, S13 or S26.

In the subroutine "Multi-AF" at step S63, a test is carried out on the condition that a group of light receiving areas C, L, R, LC and RC to be used, which one of the four predetermined position patterns a, b, c and d ( Fig. 9) has already selected or determined according to the data of the above four sensor start numbers and the four predetermined position pattern a, b, c, d, which are stored in the ROM 84. This test checks whether there is an error state (i.e. the state in which no distance can be measured) in one of the light-receiving areas C, L, R, LC and RC, and the distance values obtained with the light-receiving areas without an error state become one selected that is closest to a predetermined focusable area of the camera 11 to be used for the focus.

In the subroutine "Multi-AF" of step S63, the sensor start number currently stored in the RAM 83 is first read from the RAM 83 , and it is checked in step S90 whether it is DIV0 or not. Control goes to step S102 if it is. At step S102, the CPU 50 inputs from the ROM 84 the information about the sensor start number DIV0, that is, C_DIV0, L_DIV0, R_DIV0, LC_DIV0 and RC_DIV0, the position pattern of which is shown in Fig. 9a.

Each of these position information represents the position of the light receiving element at one end (right end in FIG. 9) of the corresponding light receiving area, which consists of 36 light receiving elements.

At step S103, the positions to be used are the Light receiving areas C, L, R, LC and RC each correspondingly the above information C_DIV0, L_DIV0, R_DIV0, LC_DIV0 and RC_DIV0 determined as follows.  

The central light receiving area C is determined by the width from the right end, ie the position C_DIV0, to the left end. The position of the left end is determined by the amount C_DIV0 + N - 1, ie 1 + N - 1. Here, N is the predetermined number of light-receiving elements, from which each light-receiving area C, L, R, LC and RC consists Case 36 . The middle light receiving area C can be expressed as area C_DIV0 ~ C_DIV0 + N - 1. The remaining light absorption areas L, R, LC and RC are each determined similarly.

The left light receiving area L is determined to be from its right end, d. H. the position L_DIV0, to its lin ken end has the length L_DIV0 + N - 1, d. H. 1 + N - 1.

The right light receiving area R is determined so that it from its right end, d. H. the position R_DIV0, to his left end has the length R_DIV0 + N - 1, d. H. 1 + N - 1.

The light receiving area LC is determined to be off a right end, d. H. the position LC_DIV0, up to his left end has the length LC_DIV0 + N - 1, d. H. 1 + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position RC_DIV0, up to his left end has the length RC_DIV0 + N - 1, d. H. 1 + N - 1.

The arithmetic operation part 31 in the distance measuring unit 18 successively sends the sensor data from each light receiving element of each light receiving area C, L, R, LC and RC to the CPU 50 in accordance with signals output by the CPU 50 . For example, if the CPU 50 needs to acquire a series of sensor data from the right light receiving area R from the ninth light receiving element (counted from the right end of the total of 128 light receiving elements) to the left end of the light receiving area R, the arithmetic operation part 31 sequentially sends that of each of the 36 light receiving elements from the above-mentioned ninth light receiving element up to the 44th light receiving element (ie 9 + 36 - 1) sensor data.

After step S103, control goes to a subroutine "Error detection" of step S96, in accordance with the entered sensor data is checked whether an error condition in one of the light receiving areas C, L, R, LC and RC occurs.

If it is determined in step S90 that the read sensor start number is not DIV0, control goes to step S91 to check whether the sensor start number is DIV1. If it is, control goes to step S104. At this step, the CPU 50 inputs the position information from the ROM 84 via the sensor start number DIV1, ie C_DIV1, L_DIV1, R_DIV1, LC_DIV1 and RC_DIV1, the position pattern of which is shown in Fig. 9b.

After that, the positions of the light exposure to be used areas C, L, R, LC and RC each corresponding to the previous one determined information as follows.

The central light receiving area C is determined by the width of the right end, d. H. the position C_DIV1 to the left End determined. The position of the left end is through the Amount C_DIV1 + N - 1 determined, i.e. H. 1 + N - 1. The middle light Recording area C can be defined as area C_DIV1 ~ C_DIV1 + N - 1 be pressed. The remaining light receiving areas L, R, LC and RC are determined similarly in each case.

The left light receiving area L is determined to be from its right end, d. H. the position L_DIV1, up to his left end has the length L_DIV1 + N - 1, d. H. 1 + N - 1.  

The right light receiving area R is determined so that it from its right end, d. H. the position of R_DIV1, up to its left end has the length R_DIV1 + N - 1, d. H. 1 + N - 1.

The light receiving area LC is determined to be off a right end, d. H. the position of LC_DIV1, up to has the length LC_DIV1 + N - 1 at the left end, d. H. 1 + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position of RC_DIV1, up to has a length of RC_DIV1 + N - 1 at the left end, d. H. 1 + N - 1.

After step S105, control goes to the subroutine "Error detection" of step S96.

If it is determined in step S91 that the read sensor start number is not DIV1, control goes to step S93 to check whether the read sensor start number is DIV2. If it is, control goes to step S106. In this step, the CPU 50 enters from the ROM 84 the position information about the sensor start number DIV2, ie C_DIV2, L_DIV2, R_DIV2, LC_DIV2 and RC_DIV2, whose position pattern is shown in FIG. 9c.

Thereafter, at step S107, the position to be used is the Light receiving areas C, L, R, LC and RC each correspondingly the above information as follows Right.

The central light receiving area C is determined by the width of the right end, d. H. the position of C_DIV2 up to lin ken end determined. The position of the left end is through the amount C_DIV2 + N - 1 are expressed, d. H. 1 + N - 1. The middle light receiving area C can be used as area C_DIV2 ~ C_DIV2 + N - 1 is determined. The other light receiving areas L, R, LC and RC are each determined similarly.  

The left light receiving area L is determined to be from its right end, d. H. the position of L_DIV2, up to its left end has the length L_DIV2 + N - 1, d. H. 1 + N - 1.

The right light receiving area R is determined so that it from its right end, d. H. the position of R_DIV2, up to its left end has the length R_DIV2 + N - 1, d. H. 1 + N - 1.

The light receiving area LC is determined to be off a right end, d. H. the position of LC_DIV2, up to has the length LC_DIV2 + N - 1 at the left end, d. H. 1 + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position of RC_DIV2, up to has a length of RC_DIV2 + N - 1 at the left end, d. H. 1 + N - 1.

After step S107, control goes to the subroutine "Error detection" of step S96.

If it is determined in step S93 that the read sensor start number is not DIV2, control goes to step S94. In this step, the CPU 50 inputs from the ROM 84 the position information about the sensor start number DIV3, ie C_DIV3, L_DIV3, R_DIV3, LC_DIV3 and RC_DIV3, whose position pattern is shown in FIG. 9d.

Thereafter, the effective position of the light becomes at step S95 recording areas C, L, R, LC and RC each corresponding to the the above information is determined as follows.

The central light receiving area C is determined by the width of the right end, d. H. the position from C_DIV3 to lin ken end determined. The position of the left end is through determines the amount C_DIV3 + N - 1, d. H. 1 + N - 1. The middle one Light receiving area C can be used as area C_DIV3 ~ C_DIV3 + N - 1 be expressed. The other light receiving areas L, R, LC and RC are determined similarly.  

The left light receiving area L is determined to be from its right end, d. H. the position of L_DIV3, up to its left end has the length L_DIV3 + N - 1, d. H. 1 + N - 1.

The right light receiving area R is determined so that it from its right end, d. H. the position of R_DIV3, up to its left end has the length R_DIV3 + N - 1, d. H. 1 + N - 1.

The light receiving area LC is determined to be off a right end, d. H. the position of LC_DIV3, up to has the length LC_DIV3 + N - 1 at the left end, d. H. 1 + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position of RC_DIV3, up to has a length of RC_DIV3 + N - 1 at the left end, d. H. 1 + N - 1.

After step S95, control goes to the subroutine "Error detection" of step S96.

It should be noted here that, according to FIG. 9, the position of the light receiving area C is not changed when the lens is moved from the wide-angle limit position to the telephoto limit position. However, the positions of the light receiving areas L, LC, RC and R are gradually moved to a more central position, ie the number of overlapping light receiving elements increases. Each light receiving area always consists of 36 light receiving elements.

In the subroutine "error detection" at step S96 it is checked whether an error condition occurs in one of the light receiving areas C, L, R, LC and RC, which are determined in accordance with the input sensor data, that is to say corresponding to the selected focal length of the lens 13 . In accordance with the result of this test, a flag is set which states that each light receiving area has no fault condition. For example, if the light-receiving areas LC and RC each show an error state, while the light-receiving areas C, L and R do not have this state, flags are set accordingly to the light-receiving areas C, L and R.

After step S96, control goes to an "arithmetic operation" subroutine of step S97. Here, a distance value is calculated for each light receiving area C, L, R, LC and RC, as described with reference to FIG. 6. The "distance value" corresponds to the length (x-B) in Fig. 6. These calculated distance values are CX, LX, RX, LCX and RCX. The greater the respective distance value, the closer the corresponding object is to the camera 11 .

After step S97, control goes to step S98. Here will the distance value X is set to 0 as the initial value.

Thereafter, it is checked at step S99 whether in the light pickup area C there is an error condition. For this purpose, it is checked whether a flag for the light receiving area C is set. Meets if not, control goes to step S100. other if it goes to step S108.

At step S100, it is checked whether the distance value CX is larger is greater than the reference distance value X, and the controller goes to step S108 if it is equal to or less than X, or to step S101 if it is larger than X. At step S101 becomes the reference distance value X by the object distance value CX replaced.

From step S108 to step S119, operations become similar those of steps S99, S100 and S101 for each further Light receiving area L, R, LC and RC performed.

This means that it is checked at step S108 whether a mistake State exists in the light receiving area LC in which the corresponding flag is checked. The control closes  Step S109 if there is no fault condition, or to Step S111 if the fault condition is given.

At step S109, it is checked whether the object distance value LCX is greater than the reference distance value X, and the Control goes to step S111 if LCX is equal to or less than X, or to step S110 if LCX is greater than X. At step S110, the reference distance value X is determined by the Object distance value LCX replaced.

In step S111, it is checked whether an error condition for the Light receiving area RC is present. This is done through testing of the corresponding flag, and control goes to step S112 if there is no error state or to step S114, if there is an error condition.

At step S112, it is checked whether the object distance value RCX is greater than the reference distance value X, and the Control goes to step S114 if RCX is equal to or less than X, or to step S113 if RCX is greater than X. At step S113, the reference distance value X is determined by the RCX object distance value replaced.

In step S114, it is checked whether an error condition for the Light receiving area L is present. For this, the will correspond de flag checked, and control goes to step S115, if there is no fault condition, or to step S117 if the fault condition is present.

At step S115, it is checked whether the object distance value LX is greater than the reference distance value X, and the Control goes to step S117 if LX is equal to or less than X or to step S116 if LX is greater than X. at Step S116 becomes the reference distance value X by the Ob ject distance value LX replaced.  

At step S117, a check is made to see if there is any light rich R an error condition is present, the corresponding is current flags checked, and control goes to step S118, if there is no fault condition or it is reset leads if the fault condition exists.

At step S118, it is checked whether the object distance value RX is greater than the reference distance value X, and the Control is returned if RX is equal to or less than Is X, or goes to step S119 if RX is greater than X is. At step S119, the reference distance value X replaced by the object distance value RX.

In accordance with the operations from step S99 to step S119, a certain value is obtained as the reference distance value X. In step S67, it is checked whether this value obtained is greater than 0. If it is equal to or less than 0, this means that an object distance value has not been calculated for the exposure (ie focusing cannot be achieved). In this case, the control proceeds to step S71 to the green lamp 12 flashing turn b and inform the Benut zer that a focus is not possible.

If the value obtained in step S67 is greater than 0, this means that an object distance value that can be used for taking a picture has been calculated, ie focusing is possible. In this case, the control proceeds to step S68 to check whether the object to the camera is at hand for a focus to 11, and control proceeds to step S71 to the green lamp 12 b flashing turn, if the object is too close , It is located in a stand From that allows focus, the control proceeds to step S69, and the green light 12 b is turned dau ernd.

As is apparent from the above description, in the camera 11 with a distance measuring device, the respective light receiving area on each line sensor 27 and 28 is changed or adjusted in accordance with the size change of the AF frame in the viewfinder image field 47 . Thus, the object or objects in the AF frame Fa, Fb, Fc or Fd are focused precisely and reliably, and the possibility of incorrectly measuring the distance of an undesired object is significantly reduced.

On the recording system of the camera 11 is a zoom lens 13 . However, the camera 11 can also have a lens whose focal length can be selected from a plurality of predetermined values, for example 38 mm, 50 mm or 70 mm. In this case, the number of positions of the light receiving areas of each line sensor corresponds to the number of possible focal lengths and is then stored in the ROM 84 . A position can then be assigned to the selected focal length.

A camera with distance measuring device is explained below. This camera is similar to the one previously described, but there are some differences. The following description therefore only concerns the construction typical for this camera. The camera is described in the fol lowing with reference to FIGS . 1 to 9, 11 to 13, 15 and 18 to 25. This camera will be referred to later in the description of an embodiment of the invention.

The viewfinder LCD 57 of the camera 11 described above displays only the AF frames Fa, Fb, Fc and Fc, as shown in FIG. 10. In contrast, the viewfinder LCD 57 of the camera 11 described below can display four further AF frames fa, fb, fc and fd within the AF frame Fa ( FIG. 18). As already mentioned, the method for measuring the distance by optionally using the light receiving areas C, LC and RC of the two line sensors 27 and 28 is referred to as "spot AF". The AF frames fa, fb, fc and fd are used when this method is carried out. This is explained in the following.

If the multi-AF operation is effective, the activated AF frame shifts from Fa to Fd when the positional pattern of the light receiving areas C, L, R, LC and RC to be used changes from a to d ( FIG. 9) becomes. If the spot AF mode is effective, the activated AF frame shifts from fa to fd when the position pattern to be used for the light receiving areas C, LC and RC is changed from a to d. With this construction, the size difference between the current light receiving area and the AF frame is almost completely reduced, and the user can thus visually check the current size of the light receiving area with a currently selected focal length.

The main feature of the camera 11 of the second game, namely the setting of the parallax between the distance measuring unit 18 and the lens 13 is explained in the following with reference to FIGS . 19 to 21.

In an ideal configuration, each optical axis of the imaging lenses 25 and 26 of the distance measuring unit 18 is parallel to the optical axis O of the lens 13 , so that no significant parallax occurs between the passive distance measuring unit 18 and the lens 13 . In Fig. 19, the optical axes of the imaging lenses 25 and 26 are shown as a single optical axis o ₁ for explanation. In practice, however, it is often the case that the optical axis o _{1 is} not exactly parallel to the optical axis O of the lens 13 , but it is offset, for example, by a small change in the size of each element of the camera 11 . Such an offset with the optical axis o ₁ shown in broken lines is shown in FIG. 19. The optical axis of the viewfinder of the camera 11 is set parallel to the optical axis O of the lens 13 , so that there is no substantial Pa rallaxe here.

In the distance measuring device, the amount of the parallax between the distance measuring unit 18 and the lens 13 is measured beforehand and stored in the ROM 84 as camera-specific data during manufacture. The CPU 50 selects a group of light receiving elements (ie, photodiodes) for distance calculation from a large number of light receiving elements of each line sensor 27 and 28 according to the data stored in the ROM 84 , whereby the parallax between the distance measuring unit 18 and the lens 13 is set without the Distance measurement unit 18 to have to move relative to the camera housing. This is explained in detail.

As shown in FIG. 20, the recorded light data is output as data A in the middle of an output diagram OC when the optical axis o _{1 of} the distance measuring unit 18 is parallel to the optical axis O of the objective 13 . In many cases, however, the same data are output as data B, which are offset from the center of the output diagram OC, because the optical axis o ₁ deviates somewhat from the optical axis O of the objective 13 , as is the case for the axis o ₁ in FIG. 19 is shown in dashed lines.

In the distance measuring device, the amount α of the parallax between the distance measuring unit 18 and the objective 13 is defined by which the data amount B is offset from the data A, ie the number of light-receiving elements by which the light-receiving areas are output by the data B, is shifted in the horizontal direction of the camera 11 relative to the light-receiving areas which emit the data A. This amount is stored in the ROM 84 as the parallax adjustment amount α, and a distance measurement is carried out with the light receiving areas of each line sensor 27 and 28 to be used, which are shifted by the parallax adjustment amount α. In other words, a distance measurement is carried out on the condition that the center of each line sensor 27 and 28 , which should normally correspond to the center C of the output diagram OC, is shifted to the position C 'by the parallax adjustment amount α. The parallax adjustment amount .alpha. Can be positive or negative depending on the direction of displacement, that is, if the light-receiving areas outputting data B differ from the light-receiving areas outputting data A in one direction or the other (to the right or to the left in FIG. 20) ,

The parallax adjustment amount α is measured during assembly of the camera 11 with a line gauge LC shown in FIG. 19. The camera 11 of the line gauge LC is turned so that the ideal optical axis o _{1 is} parallel to the optical axis O's of the lens 13 and is aligned with a vertical center line L on the line gauge LC.

In order to correct the parallax between the distance measuring unit 18 and the lens 13 , each line sensor 27 , 28 consists of more than 128 light receiving elements, since the effective light receiving areas C, L, R, LC and RC together to the right or left opposite the center of each Linensens ors 27 , 28 are to be moved. In addition to the 128 light receiving elements in the middle, a predetermined number of light receiving elements is provided at the left and right ends of each line sensor 27 and 28 . For example, each line sensor 27 , 28 can consist of more than 148 light recording elements. In the case considered here, ten light receiving elements are added to the right and left ends of each line sensor 27 , 28 . The number of additional light receiving elements is predetermined so that it corresponds to a _maximum parallax adjustment amount ± α _max . In other words, the number of light receiving elements at the left end of each line sensor 27 , 28 corresponds to a maximum parallax adjustment amount -α, and the number of additional light receiving elements at the right end of each line sensor 27 , 28 corresponds to a maximum parallax adjustment amount + α.

Fig. 21a and b each show the line sensor 27 and 28, the distance measuring unit 18 in the camera 11. In Fig. 21a, the additional light receiving elements are shown hatched at the right and at the left end of a line sensor. Their number corresponds to the above-mentioned maximum parallax correction amount ± α _max .

The function of the camera 11 is explained below. The main routine performed by the CPU 50 is the same as that of Figs. 11 to 13.

Fig. 22 shows a subroutine "Recording" of the camera 11. This subroutine corresponds to the corresponding one in the camera 11 according to FIG. 14 with the difference that here a subroutine "distance measurement" is provided in step S630 before step S64 instead of the subroutine "multi-AF operation". Accordingly, control transfers to the distance measurement subroutine in step S630 if no error is detected in step S62. This subroutine is shown in Fig. 23.

In step S190, the CPU 50 inputs the sensor data of the distance measuring unit 18 and thereafter in step S191 the parallax adjustment amount + α or -α that was stored in the ROM 84 when the camera was manufactured. Thereafter, it is checked at step S192 whether the multi-AF operation is selected, and then control goes to the "Multi-AF operation" subroutine of step S194, otherwise to step S193.

At step S193, it is checked whether the spot AF mode is selected is so that control becomes a subroutine "Spot AF Opera "of step S195 goes, otherwise it goes to one Macro AF operation subroutine of step S196.

Fig. 24, the subroutine "Multi-AF operation" indicates the step S194.

The four sensor start numbers DIV0, DIV1, DIV2 and DIV3, which correspond to the first, second, third and fourth section of the zoom range of the lens 13 , determine the position of each light receiving area C, L, R, LC and RC and are in the RAM 83 saved. They result from the information provided by the lens information reading circuit 78 when the focal length is changed or the macro operation is performed in accordance with the operation at step S10, S13 or S26.

In the subroutine "Multi-AF operation" of step S194, on the condition that a group to be used for light receiving areas C, L, R, LC and RC, which one of the four predetermined position patterns a, b, c, d ( Fig. has 9), already accordingly the data of the above-mentioned four Sensorstartnum numbers and the four predetermined position patterns a, b, was c and d selected in the ROM 84 or determined, each light onto take-up zone C, L, R, LC and RC checked for an error condition (ie, a condition in which a distance value cannot be measured), and from the distance values obtained with the light receiving areas without an error condition, the one closest to the lens in a predetermined focusable range of the camera is selected adjust.

In the "Multi-AF operation" subroutine of step S194, the sensor start number stored in the RAM 83 is read, and it is checked in step S197 whether it is DIV0. If it is, control goes to step S199. Here, the CPU 50 inputs from the ROM 84 the information about the sensor start number DIV0, ie C_DIV0, L_DIV0, R_DIV0, LC_DIV0 and RC_DIV0, the respective position patterns of which are shown in FIG. 9a.

Each of these position information represents the position of the light receiving element at one end (right end in FIG. 9) of the corresponding light receiving area, which consists of 36 light receiving elements.

At step S200, the CPU 50 inputs the parallax setting amount α stored in the ROM 84 , and the position information C_DIV0, L_DIV0, R_DIV0, LC_DIV0 and RC_DIV0 entered at step S199 are respectively set in accordance with the input parallax setting amount α, and thereafter are set positions of use of the light receiving areas D, L, R, LC and RC are determined in accordance with the above-mentioned set information as follows.

The central light receiving area C is determined by the width from right end, d. H. the position C_DIV0 ± α, up to the left En de determined. The position of the left end is through the Be trag C_DIV0 ± α + N - 1 determined, d. H. 1 ± α + N - 1. As mentioned before, N is the number of light receiving elements of each light recording area C, L, R, LC and RC, d. H. 36. Is the Pa rallaxenstellmenge α positive, the value + α becomes the Position information added. If it is negative, it will Subtracted from the position information.

The middle light receiving area C can be called area C_DIV0 ± α ~ C-DIV0 ± α + N - 1 can be expressed. The rest of the lights L, R, LC and RC ranges are determined similarly.

The left light receiving area L is determined to be from its right end, d. H. the position L_DIV0 ± α, up to left end has the length L_DIV0 ± α + N - 1, d. H. 1 ± α + N - 1.  

The right light receiving area R is determined so that it from its right end, d. H. the position R_DIV0 ± α, up to left end has the length R_DIV0 ± α + N - 1, d. H. 1 ± α + N - 1.

The light receiving area LC is determined to be off a right end, d. H. the position LC_DIV0 ± α, up to the lin ken end has the length LC_DIV0 ± α + N - 1, d. H. 1 ± α + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position RC_DIV0 ± α, up to the lin ken end has the length RC_DIV0 ± α + N - 1, d. H. 1 ± α + N - 1.

The arithmetic operation part 31 in the distance measuring unit 18 sequentially sends the sensor data output by each light recording element in each light receiving region C, L, R, LC and RC to the CPU 50 in accordance with signals output by the CPU 50 . Must the CPU 50 e.g. B. a series of sensor data from the right light receiving area R from the 9 ± αth light receiving element (counted from the right end of the total of 128 light receiving elements) to the left end of the light receiving area R, the arithmetic operation part 31 sends successively those of each of the 36 light receiving elements elements from the 9 ± αth light receiving element to the 9 ± α + 35th light receiving element, ie 9 ± α + 36 - 1, output sensor data.

After step S200, control goes to a subroutine "Error detection" of step S208, with the corresponding to the entered sensor data is checked whether an error condition in one of the light receiving areas C, L, R, LC and RC lies.

If it is determined in step S197 that the read sensor start number is not DIV0, control goes to step S198 to check the sensor start number for the value DIV1. If this value is present, control goes to step S202. Here, the CPU 50 inputs from the ROM 84 the position information about the sensor start number DIV1, ie C_DIV1, L_DIV1, R_DIV1, LC_DIV1 and RC_DIV1, the position pattern of which is shown in FIG. 9b.

Thereafter, the CPU 50 inputs the parallax adjustment amount ± α stored in the ROM 84 in step S203, and the above-mentioned position information entered in step S202 is respectively set in accordance with the parallax adjustment amount α, and thereafter the positions of the light receiving areas to be used C, L, R, LC and RC each determined depending on the information set as follows.

The central light receiving area C is determined by the width from right end, d. H. the position C_DIV1 ± α, up to the left En de determined. The position of the left end is through the Be trag C_DIV1 ± α + N - 1 determined, d. H. 1 ± αN-1. The middle light Recording area C as area C_DIV1 ± α ~ C_DIV1 ± α + N - 1 be pressed. The remaining light receiving areas L, R, LC and RC are determined similarly.

The left light receiving area L is determined so that it from right end, d. H. the position L_DIV1 ± α, up to the left En de has the length L_DIV1 ± α + N - 1, d. H. 1 ± α + N - 1.

The right light receiving area R is determined so that it from the right end, d. H. the position R_DIV1 ± α, to the left End has the length R_DIV1 ± α + N - 1, i.e. H. 1 ± α + N - 1.

The light receiving area LC is determined so that it from right end, d. H. the position LC_DIV1 ± α, to the left End has the length LC_DIV1 ± α + N - 1, i.e. H. 1 ± α + N - 1.

The light receiving area RC is determined so that it from right end, d. H. the position RC_DIV1 ± α, to the left End has the length RC_DIV1 ± α + N - 1, i.e. H. 1 ± α + N - 1.  

After step S203, control goes to a subroutine "Error detection" of step S208.

If it is determined in step S198 that the read sensor start number is not DIV1, control goes to step S201 to check whether the sensor start number is DIV2. If so, control transfers to step S204. Here, the CPU 50 enters the position information from the ROM 84 via the sensor start number DIV2, ie C_DIV2, L_DIV2, L_DIV2, LC_DIV2 and RC_DIV2, the respective position patterns of which are shown in FIG. 9c.

Thereafter, the CPU 50 inputs the parallax setting amount ± α from the ROM 84 at step S205, and the position information input at step S204 is set according to the input parallax setting amount ± α, respectively, and then the positions of the light receiving areas C, L to be used , R, LC and RC each determined in accordance with the above-mentioned set information.

The central light receiving area C is determined by the width from right end, d. H. the position C_DIV2 ± α, up to the left En de determined. The position of the left end is through the Be trag C_DIV2 ± α + N - 1 determined, d. H. 1 ± α + N - 1. The middle one Light receiving area C can be used as area C_DIV2 ± α ~ C_DIV2 ± α + N - 1 can be expressed. The other light receiving areas L, R, LC and RC are each determined similarly.

The left light receiving area L is determined to be from its right end, d. H. the position L_DIV2 ± α, up to left end has the length L_DIV2 ± α + N - 1, d. H. 1 ± α + N - 1.

The right light receiving area R is determined so that it from the right end, d. H. the position R_DIV2 ± α, to the left End has the length R_DIV2 ± α + N - 1, i.e. H. 1 ± α + N - 1.  

The light receiving area LC is determined to be off a right end, d. H. the position LC_DIV2 ± α, up to the lin ken end has the length LC_DIV2 ± α + N - 1, d. H. 1 ± α + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position RC_DIV2 ± α, up to the lin ken end has the length RC_DIV2 ± α + N - 1, d. H. 1 ± α + N - 1.

After step S205, control goes to the subroutine "Error detection" of step S208.

If it is determined in step S201 that the read sensor start number is not DIV2, control goes to step S206. Here, the CPU 50 outputs from the ROM 84 the position information of the sensor start number DIV3, ie C_DIV3, L_DIV3, R_DIV3, LC_DIV3 and RC_DIV3, the position pattern of which is shown in FIG. 9d.

Thereafter, the CPU 50 inputs the parallax adjustment amount ± α from the ROM 84 in step S207, and the position information input in step S206 is set in accordance with the input parallax adjustment amount ± α, after which the positions of the light receiving areas C, L, R, LC and RC can each be determined in accordance with the information set.

The central light receiving area C is determined by the width from right end, d. H. the position C_DIV3 ± α, up to the left En de determined. The position of the left end is through the Be trag C_DIV3 ± α + N - 1 determined, d. H. 1 ± α + N - 1. The middle one Light receiving area C can be used as area C_DIV3 ± α ~ C_DIV3 ± α + N - 1 can be expressed. The other light receiving areas L, R, LC and RC are each determined similarly.

The left light receiving area L is determined to be from its right end, d. H. the position L_DIV3 ± α, up to left end has the length L_DIV3 ± α + N - 1, d. H. 1 ± α + N - 1.  

The right light receiving area R is determined so that it from its right end, d. H. the position R_DIV3 ± α, up to left end has the length R_DIV3 ± α + N - 1, d. H. 1 ± α + N - 1.

The light receiving area LC is determined to be off a right end, d. H. the position LC_DIV3 ± α, up to the lin ken end has the length LC_DIV3 ± α + N - 1, d. H. 1 ± α + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position RC_DIV3 ± α, up to the lin ken end has the length RC_DIV3 ± α + N - 1, d. H. 1 ± α + N - 1.

After step S207, control goes to the subroutine "Error detection" of step S208.

In this subroutine it is checked whether an error condition occurs in one of the light receiving areas C, L, R, LC and RC, which are determined in accordance with the sensor data entered, ie in accordance with the selected focal length of the lens 13 . Depending on the result of this test, a marker is set for each light receiving area without a fault condition. If the light receiving areas LC and RC each have an error state while the other areas C, L, R have no error state, flags for the light receiving areas C, L, R are set.

After step S208, control goes to an "arithmetic operation" subroutine of step S209. Here, a distance value is calculated for each light receiving area C, L, R, LC and RC, as described with reference to FIG. 6. These are the distance values CX, LX, RX, LCX and RCX. The greater the distance value, the closer the object is to the camera 11 .

Then control goes to a subroutine "Select calculated distance value" of step S210. This subroutine contains the same steps as steps S98 to S119 of the "Multi-AF" subroutine in FIGS . 16 and 17. In the "Select calculated distance value" subroutine, a specific value results as the distance value X. At the end of this subroutine, there is a return Control back.

In the following the subroutine "spot AF operation" will be explained in the step S195 with reference to FIG. 25. In this subroutine, each light receiving area C, L, R, LC and RC, which has been set to one of four position patterns a, b, c and d ( FIG. 9) according to the set focal length, is shifted by the parallax setting amount a, and it it is checked whether an error state (ie a state in which no distance can be measured) is present in one of the light receiving areas C, L, R, LC and RC. From the distance values of the light-receiving areas without an error state, a distance value is selected within a predetermined sharply adjustable range and with the smallest distance to the camera 11 for focusing.

When control enters the "Spot AF Operation" subroutine at step S195, the light receiving areas C, L, R, LC and RC are each shifted by the parallax adjustment amount α read from the ROM 84 and used in step S211 set in the spot AF operation. The control then goes to a subroutine "error detection" of step S212, in which a check is made in accordance with the sensor data entered as to whether an error condition is present in one of the light receiving areas C, LC and RC. Then, the control goes to a subroutine "distance calculation" of step S213, in which a distance value for each light receiving area C, LC and RC is calculated.

After step S213, control proceeds to step S214 check for a fault condition in the middle light intake area C is present. If this is not the case, the tax is paid to step S216. In the event of an error, the control goes  to step S215. At step S216, the distance value of the middle light receiving area C as one for the value to be used for photographic recording. at Step S215 checks whether in both light receiving areas Chen LC and RC there is an error state. If this is the case, then Control goes to step S217, otherwise to step S218. In step S217, it is decided that there is no removal value, and control is returned.

At step S218, it is checked whether one of the light receptacles areas LC and RC there is no error condition, and hits if it is, then control goes to step S220. Otherwise she goes to step S219. At step S220, the distance value from the light receiving areas LC and RC, which the Camera is closer, selected for photographing.

At step S219, it is checked whether in the light receiving area LC has an error state and the control system closes Step S222 if so. She goes to step S221, if there is no fault condition. At step S222, the Distance value of the light receiving area RC for the picture selected while the distance value of the light reichs LC is selected for recording at step S221. The Control becomes after step S221 or after step S222 recycled.

The foregoing discussion indicates that with the camera 11 having a distance measuring the parallax between the integrated Entfernungsmeßein 18 and the lens 13 without moving the distance measuring unit 18 can be adjusted relative to the camera body. This results in a simpler setting operation.

An embodiment of a camera with a distance measuring device according to the inven tion is explained below. This camera is similar to the two cameras described above, but has some differences, and only these differences are explained below. This camera is described below with reference to FIGS. 1 to 9, 11 to 13, 15 to 18 and 26 to 31 be.

The viewfinder LCD 57 of the camera 11 described first displays only the AF frames Fa, Fb, Fc and Fd, as shown in FIG. 10. On the other hand, the viewfinder LCD 57 of the camera 11 of the embodiment according to the invention described as second corresponds to that of the camera 11 , ie four further AF frames fa, fb, fc and fd can be displayed within the AF frame Fa. These AF frames take effect with "Spot AF". The control of the viewfinder LCD 57 in the spot AF operation of the embodiment is the same as that of the camera described second.

The camera 11 contains a macro mode in addition to the normal shooting mode. The macro mode can be selected by the user by actuating the macro switch 46 . In this camera 11 , the AF frame fd is not only used as an AF frame corresponding to the telephoto limit position in spot AF mode, but also as an AF frame in macro mode. If the macro mode is selected, only the AF frame fd is visible or switched on, the remaining AF frames are switched off altogether.

The optical axis of the viewfinder of the camera 11 is set parallel to the optical axis O of the lens 13 , so that no significant parallax occurs here.

The main feature of the camera 11 of the exemplary embodiment, ie the correction of a difference in the positions of the AF frame fd in the viewfinder image field 47 and the actual light receiving area of each line sensor 27 and 28 when the macro mode is selected, is explained below.

The distance measuring unit 18 is generally attached to the camera 11 so that each optical axis o of its two imaging lenses 25 and 26 is parallel to the optical axis O of the lens 13 , as shown in FIG. 26. Here the optical axes of the imaging lenses 25 and 26 are shown as a single optical axis o. With this configuration, a large difference or a large distance between the positions occurs on each line sensor 27 and 28 once the object has a predetermined distance from the camera 11 , e.g. B. in an area b of the normal picture, and when the object of the camera 11 is fairly close to another, e.g. B. in an area a in macro mode. For this reason, the positions of an AF frame in the field of view and the light recording area of each line sensor do not correspond exactly to one another in a conventional camera, especially in macro mode.

In order to solve the above problem, the change or shift of the two light receiving areas, ie the first light receiving area on each line sensor 27 and 28 , onto which the light of the object falls in area b during normal recording, and the second light receiving area one of each the line sensor 27 and 28 , on which the object light falls in the area of the macro mode, is stored in the ROM 84 during the camera assembly as a setting date (information C_MAC, LC_MAC, RC_MAC regarding the sensor start number). When changing from normal recording to macro recording, a group of light recording elements (ie photodiodes) is selected for macro recording from a large number of light recording elements in each line sensor 27 and 28 according to the setting date in ROM 84 . When the macro mode is set with the macro switch 46 , the CPU 50 automatically changes the light receiving areas of each line sensor 27 , 28 used for the normal shot to those for the macro shot, which is shown in FIG. 27.

In normal exposure, the light exposure areas C, LC and RC are each arranged in their normal positions as group D, as shown in FIG. 27. When these light receiving areas C, LC and RC of group D receive object light, they output the data A in the middle of the output diagram OC. In macro mode, however, the light recording areas C, LC and RC are in a position shifted to the left by a predetermined amount with respect to the normal position and form group E shown there in FIG. 27. The predetermined amount of shift corresponds to the parallax between the optical axis o the line sensors 27 , 28 and the optical axis of the objective 13 . When the light receiving areas C, LC and RC of group E receive object light, data B is output in a position to the left of data A. As shown in FIG. 28, the center of the light receiving areas C, LC 12400 00070 552 001000280000000200012000285911228900040 0002019655198 00004 12281 and RC, which is effective in normal shooting, is arranged on a line G, and this center shifts to the left in macro mode by a predetermined number of light receiving elements ,

In Figs. 27 and 28 are only three light receiving areas C, LC and RC for each line sensor 27, 28 are shown, uses because the spot AF operation be for distance measurement in the macro mode, will be such that the other light receiving areas L and R is not used here ,

The operation of the camera 11 of the embodiment will be explained below. The main routine performed with the CPU 50 corresponds to that of the camera 11 of the first exemplary embodiment according to FIGS. 11 to 13.

In the camera 11 of the embodiment, the subroutine "recording" shown in FIG. 14 is replaced by that shown in FIG. 29. Steps common to both subroutines have the same numbering, and no explanation of these steps is given.

Before step S64, a "distance measurement" subroutine is carried out at step S363. This subroutine is shown in FIG. 30 and essentially coincides with the "range measurement" subroutine of the camera 11 according to FIG. 23 with the difference that the subroutine shown in FIG. 30 does not include step S191. The steps common to both subroutines have the same numbering, and an explanation of these steps is omitted. After step S363, control goes to step S64, then to step S65, and finally to step S346.

Here it is checked whether the macro mode is selected, so that control then goes to step S347. Otherwise she leaves to step S67. At step S67, it is checked whether a removal value that can be used for the recording can be calculated can (i.e. whether there is an error in the distance calculation lies).

Is decided at step S347 that a usable for receiving distance value has not been calculated (that is, that an error in the calculation occurs), then the control proceeds to step S71, b to the green lamp 12 flashing on and to inform the user that focusing is impossible. On the other hand entschie to that a usable for receiving distance value be calculated (ie, the distance calculation contains no error), the control proceeds to step S348, b to the green lamp 12 permanently turn on and the user to precise information ren at step S347, that focusing is possible.

The "Multi AF Operation" subroutine of step S194 in FIG. 30 is the same as that of FIGS . 16 and 17. In the subroutine of step S194 in Fig. 30, the four sensor start numbers DIV0, DIV1, DIV2 and DIV3, each corresponding to the first, second, third and fourth sections of the zoom range of the lens 13 , determine the position of each light receiving area C, L , R, LC and RC and are stored in the RAM 83 in accordance with information read by the reading circuit 78 when the focal length is changed or the macro mode is turned on, in accordance with the operation in step S10, S13 or S26.

The "Macro AF operation" subroutine at step S196 in Fig. 30 is shown in Fig. 31 and will be explained below.

In the "Macro AF operation" subroutine, a group of light receiving areas of each line sensor 27 , 28 , which is used for normal recording, is shifted for the macro mode by a predetermined amount, so that an accurate distance measurement in the macro mode can be achieved even if the optical axis o of the distance measuring unit 18 we deviates significantly from the optical axis O of the lens 13 in the horizontal direction of the camera 11 .

When control enters the "Macro AF operation" subroutine, the CPU 50 first inputs the information on the read sensor start number, that is, C_MAC, LC_MAC and RC_MAC (ie, change data) from the ROM 84 in step S323. Then, at step S324, the positions of the light receiving areas C, LC and RC are determined according to this information as follows.

The central light receiving area C is determined by the width of the right end, d. H. the position C_MAC to the left En de determined. The position of the left end is through the Be letter C_MAC + N - 1 determines, d. H. 1 + N - 1. Here N is the number of Light receiving elements of each light receiving area C, LC and RC, d. H. 36. The middle light receiving area C can be as Range C_MAC ~ C_MAC + N - 1 can be expressed. The remaining Light receiving areas LC and RC are each similar Right.  

The light receiving area LC is determined to be off a right end, d. H. the position LC_MAC to the left End has length LC_MAC + N - 1, i.e. H. 1 + N - 1.

The light receiving area RC is determined to be off a right end, d. H. the position RC_MAC to the left End has length RC_MAC + N - 1, i.e. H. 1 + N - 1.

After step S324, control goes to a subroutine "Error detection" at step S325. Here it is checked whether a Fault condition in one of the light receiving areas C, LC and RC that are suitable for macro operation.

Depending on the result of this check at step S325 is entered for each light receiving area without an error condition Flag set. For example, it was used for Rich LC detects an error condition, while this occurs in the Light receiving areas C and RC will not be the case only flags set for the light receiving areas C and RC.

After step S325, control goes to an "arithmetic operation" subroutine of step S326. Here a distance value CX, LCX and RCX is calculated for each light receiving area C, LC and RC. The greater the distance value, the closer the corresponding object is to the camera 11 .

After the "arithmetic operation" subroutine at step S326, it is checked again whether an error condition occurs in a light receiving area C, LC and RC suitable for macro shooting, and whether each calculated distance value CX, LCX and RCX is in a recordable area is, that is, in the macro area a shown in FIG. 26.

First, at step S327, it is checked whether the light is on range C there is no fault condition and the calculated one Distance value CX is in a recordable range, and  control goes to step S328 if no fault condition is available and the calculated distance value can be used. at Step S328, the calculated distance value CX becomes Ent distance value for focusing, and then control returns. If an error at step S327 state for the light receiving area C is determined and / or the calculated distance value CX outside of is within the acceptable range, control goes to step S329.

Here it is checked whether there is no fault condition in the light receptacle m range LC or RC is present, so that the control is then closed Step S331 can go. But if in one of the areas LC and RC is in an error condition, it goes to step S330.

At step S331, it is checked whether both calculated distances LCX and RCX values outside the recordable range and control passes to step S332 if it is meets. At step S332, it is decided that there is no be calculated distance value, after which the control returns versa. If the calculated distance value at step S331 LCX or RCX is within the recordable range control to step S333 where the reference range value X is set to 0 as the initial value. Then the Control of step S334.

At step S334, it is checked whether the calculated distance worth LCX is in the recordable range, and meets this control goes to step S335, otherwise control Step S336. At step S335, the reference distance value X replaced by the calculated distance value LCX. because control goes to step S336.

At step S336, it is checked whether the calculated distance worth RCX is in the recordable range, and if so if true, control goes to step S337, otherwise it will be returned. At step S337, it is checked whether the  calculated distance value RCX greater than the reference ent distance value is X, and if so, the tax is eliminated tion to step S338 or is returned if the calculated distance value RCX equal to or less than that Reference distance value X is. At step S338, the Re Reference distance value X by the calculated distance value replaced RCX, after which control returns.

At step S330, it is checked whether there are light in both if there is a fault condition in LC and RC, and if so if true, control goes to step S339, otherwise Step S340. At step S339, it is decided that it does not gives a calculated distance value, after which the control is returned.

At step S340, it is checked whether there is a fault condition in the light recording area LC is present, and if this is the case, then the Control to step S342, otherwise to step S341. at Step S342 checks whether the calculated distance value RCX is in the recordable range, and if so control passes to step S343, otherwise Step S345. At step S343, the reference distance value X replaced by the calculated distance value RCX. because after that the control returns. At step S345, ent decided that there is no calculated distance value where after the control is returned.

At step S341, it is checked whether the calculated distance worth LCX is in the recordable range, and if so if true, control proceeds to step S344, otherwise Step S345. At step S344, the reference distance value X replaced by the calculated distance value LCX. because after the control is returned.

According to the operations of steps S327 to S345, a certain value is obtained as the reference distance value X. At step S347 in Fig. 29, it is checked whether this value is greater than 0. If it is greater or less than 0, this means that a distance value that can be used for focusing has not been calculated (ie focusing is impossible). In this case, the control proceeds to step S71 to the green lamp 12 flashing turn b and to inform the user that the focus is impossible.

On the other hand, if the value obtained at step S347 is greater than 0, this means that a distance value usable for the focusing has been calculated (ie focusing is possible). In this case, the control proceeds to step S348 comes, and the green light 12, a b connected to inform the user that the focus is achieved.

As is apparent from the above description, in the camera 11 with a distance measuring device according to the invention, when the macro mode is selected, the light receiving area on each line sensor 27 and 28 is changed or adjusted to speak the AF frame for macro shooting in the viewfinder image field 47 , In the exemplary embodiment, therefore, the object or objects within the macro AF frame are focused precisely and reliably, and the possibility is reduced that the distance of an undesired object is incorrectly measured as the shooting distance.

Claims (2)

1. Distance measuring device for a camera, which can be set to a macro range for close-ups, each with a plurality of light-receiving elements consisting of line sensors, on each of which an object image is generated, characterized by a memory for predetermined correction data, which is the amount for each line sensor Indicate deviation between a first group of light-receiving elements on which the object image falls during normal recording and a second group of light-receiving elements on which the object image falls upon close-up by a device for selecting a group of light-receiving elements in accordance with the predetermined correction data derive electrical signals only from these light-receiving elements, and by means of a device for calculating a distance value using image data derived from the electrical signals. 2. Distance measuring device according to claim 1, characterized through a switch controlling the selector to Switch between normal and close-up.