JPH07333721A - Camera provided with magnetic recording function - Google Patents

Abstract

PURPOSE:To keep reliability of data high while preventing erroneous double exposure from being done at the time of reuse of a film in a camera which is provided with a magnetic recording function and whose reeling up speed is changeable. CONSTITUTION:A camera provided with a magnetic recording function is one which can write magnetically written data of photographing information, etc., in a magnetic recording part formed in a film by a magnetic signal writting head 36. Reeling up mode can be changed by reeling up mode setting switches SW5, SW6 into a normal reeling up mode in which a film can be reeled up at normal reeling up speed and a special reeling up mode in which a film is reeled up at speed different from that of the normal reeling up speed. In the case the reeling up mode is switched to the special reeling up mode, a data setting means 61 sets specific data previously set independently of the actually exposed state as magnetically written data in stead of assigned data.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a camera having a magnetic recording function for recording predetermined data in a magnetic recording portion provided on a film.

[0002]

2. Description of the Related Art Generally, in a camera having a magnetic recording function as described above, data relating to photographic information is recorded at a recording position determined for each frame. The recorded data is read out at the time of printing in the laboratory and used as reference data for printing, or printed on the front or back surface of the printed printing paper.

[0003]

Some conventional cameras have a winding mode for winding a film, a normal winding mode for winding at a normal winding speed, and a special winding mode for winding at a speed different from the normal winding speed (for example, There is a winding mode switching function that switches between high-speed winding mode that winds at high speed and silent winding mode that winds at low speed.

However, in general, the optimum speed for carrying out the magnetic recording is the normal winding speed. For example, when the high speed winding mode is selected, the moving speed of the film during data writing is too high. In addition, the recording frequency becomes very high, and there is a possibility that erroneous data may be written due to the response characteristics of the writing circuit and minute speed fluctuations. On the contrary, when the silent winding mode is switched, the film speed cannot follow the recording characteristics of the data by the magnetic signal writing head because the speed fluctuation becomes large due to the jitter due to the PWM control, etc. There is a risk of being lost. When such a situation occurs, processing is performed based on the data in which the write failure occurs, which causes various troubles and confusion. In addition to the write failure data, the write operation is normally performed. Even the data may lose its reliability.

As a countermeasure for this case, it is conceivable to stop the recording of data in the special winding mode. In this case, the film in which only a part of the frame has been exposed is rewound once in this partially exposed state. And reuse
At the start of reuse, the data was not written for the frame for which recording was stopped, so this frame was erroneously detected as an unexposed frame, and double exposure was erroneously started from this frame. There is a risk that

In view of such circumstances, the present invention makes it possible to increase the reliability of data in a camera with a magnetic recording function whose winding speed can be switched, while preventing accidental double exposure when the film is reused. The purpose is to provide what can be maintained.

[0007]

As a means for solving the above-mentioned problems, the present invention is to mount a film having a magnetic recording portion, and to correspond to the exposure state of each frame of the film, the magnetic recording portion In a camera having a magnetic recording function for recording data, a film feeding means for winding and rewinding the film, and a magnetic signal writing for recording data corresponding to each frame in the magnetic recording unit at the time of winding the film. Means, data setting means for setting the magnetic writing data to be written in the magnetic recording section by the magnetic signal writing means, and film winding mode by the film feeding means so that normal data writing can be performed by the magnetic signal writing means. Special winding to wind the film at a normal winding mode and at a speed different from the above normal winding speed. And winding-up mode switching means for switching to the magnetic field, and when winding in the special winding mode, the preset special data is set as the magnetic writing data regardless of the exposure state of the frame. It constitutes a setting means.

[0008]

According to the above-mentioned camera, in the special winding mode in which it is difficult to write normal data, instead of the normal data corresponding to the exposure state of the actual frame, certain special data irrelevant to the exposure state is magnetically recorded. Because it is written in the department,
At the time of processing the film after the end of shooting, it is possible to accurately determine from the writing of the special data that the frame corresponding to this data has been wound in the special winding mode, thereby avoiding unnecessary confusion.
Also, unlike the case of prohibiting the data writing itself in the special winding mode, the above-mentioned data writing prohibited frame is not erroneously detected as an unexposed frame during the next use, and double exposure is erroneously performed from this frame. The inconvenience caused is surely prevented.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the drawings.

A camera (camera with a magnetic recording function) 10 shown in FIG. 2 is equipped with a take-up spool 12 at one end thereof.
The film cartridge 14 is detachably attached to the other end.

The film cartridge 14 has a film 18 wound around a sleeve 16 as shown in FIG. 3, and the film 18 pulled out from the film cartridge 14 is wound around the take-up spool 12. ing. Then, in the camera 10, a rotary fork (not shown) with which the lower end 17 of the sleeve 16 is engaged and the take-up spool 12 are connected to a single feeding motor 13 shown in FIG. 10 via a drive transmission mechanism. , The take-up spool 1 by the feeding motor 13
2 and the sleeve 16 are interlocked with each other. When the feeding motor 13 rotates in the normal direction, the film 18 is wound (that is, fed from the film cartridge 14 to the take-up spool 12) and vice versa. When the feeding motor 13 is rotated in the reverse direction, rewinding from the take-up spool 12 to the film cartridge 14 is performed.

A disk 20 is fixed to the lower end of the sleeve 16. As shown in FIGS. 4A to 4C, the surface of the disk 20 is a bar code in which black and white are alternately arranged in the circumferential direction, and the bar code is film information, for example, the type of film. (Negative / Positive /
(Black and white, etc.), ISO sensitivity, number of frames, etc. On the other hand, in the two positions P1 and P2 arranged in the circumferential direction of the disc 20 in the camera 10, the bar code portions corresponding to the positions P1 and P2 are used to determine whether the bar code portions are white or black. A photo reflector is provided.

An arrow-shaped display member 22 as shown in FIG. 5 is fixed to the upper end of the sleeve 16.
An unexposed display mark 24, a partially exposed display mark 25, and an exposed display mark 26 are arranged in the circumferential direction on the upper surface of the film cartridge 14 so as to surround the display member 22. Then, as shown in FIG. 4A, the display member 22 indicates the unexposed display mark 24 in the state where the white portion of the disk 20 is detected at both the positions P1 and P2, and as shown in FIG. As described above, the white portion of the barcode is at the position P1, and the disc 20 is at the position P2.
In the state where the black portions of the
2 indicates the above-mentioned partial exposure display mark 25, and FIG.
In the state where the black portion of the disk 20 is detected at both positions P1 and P2 as shown in FIG. 5, the phase of the display member 22 with respect to the disk 20 in the circumferential direction is set so that the display member 22 indicates the exposed display mark 26. It is set.

As shown in FIG. 6, a plurality of frames (exposure parts) 28 are arranged in the longitudinal direction of the film 18, and one edge of the film 28 corresponds to both ends of each frame 28. A perforation (through hole) 30 is formed at the position, and the presence of the perforation 30 is detected by the photo reflector 32, so that the feeding state of the film 16 is detected.

A strip-shaped magnetic recording portion 34 is provided at the other edge of the film 18 corresponding to each frame 28, and a magnetic writing head 36 (FIG. 2) is formed on the magnetic recording portion 34 when the film 18 is wound. Data relating to photographing information and the like is written by, and the above data is read by the magnetic reading head 38 when the film 18 is rewound. Therefore, as shown in FIG.
For No. 8, data is written in the magnetic recording unit 34, and for unexposed frames 28, no data is written in the magnetic recording unit 34. Therefore, the presence or absence of data in the magnetic recording unit 34 is detected when the film 18 is fed. By
It is possible to grasp how far the film 18 is exposed.

As the data to be written in the magnetic recording portion 34, the data shown in Table 1 below is prepared in this embodiment. Here, in the magnetic recording unit 34, for one type of data, as shown in FIG. 7, a start signal 35A indicating the start of the data, the type of the data, etc. (that is, which of the data in Table 1 ID signal 35B, data signal 35C indicating the content of the data, and end signal 35D indicating the end of the data are successively written.

[0017]

[Table 1]

The camera 10 includes a photographing preparation switch SW1, a release switch SW2, a multiple exposure number setting switch SW3, a multiple exposure mode setting switch SW4, and a silent feeding mode setting switch SW as shown in FIG.
5, high speed feeding mode setting switch SW6, rewinding switch SW7, feeding amount detecting circuit 40, film winding stop position detecting circuit 42, data disc reading circuit 44, cartridge loading detecting circuit 45, user information input circuit 46,
A photometric circuit 47, a distance measuring circuit 48, and a magnetic signal reading circuit 50 are provided, and their output signals are input to the microcomputer 60.

The photographing preparation switch SW1 is turned on when a release button (not shown) is half-depressed, and a command signal for performing photometry and distance measurement is input to the microcomputer 60 when the release button is turned on. It is a thing. The release switch SW2 is turned on when the release button is completely pressed, and an exposure command signal is input to the microcomputer 60 at the time of this on-switching.

The multiple exposure number setting switch SW3 counts the number of times it is pressed in the microcomputer 60, and the count number is set as it is as the multiple exposure number setting switch SW3.
Reference numeral 4 sets the exposure mode to the normal exposure mode (a mode in which winding is performed each time one exposure is performed on one frame 28) and multiple exposure mode (one frame 28 is set by the multiple exposure number setting switch SW3). This is for switching to a mode in which the film is wound up after the exposure is repeated for the number of times that has been performed.

Silent winding mode setting switch SW
5 and the high-speed winding mode setting switch SW6 are for switching the film winding mode. As will be described later, when both switches SW5 and SW6 are off, the film winding mode is switched to the normal winding mode.
When the silent winding mode setting switch SW5 is turned on, the film winding mode is switched to the silent winding mode (mode in which the feeding motor 13 shown in FIG. 10 performs low-speed feeding by performing PWM control or the like), and the high-speed winding mode is set. When the setting switch SW6 is turned on, the film winding mode is switched to the high-speed winding mode (a mode in which the external auxiliary power supply 74 shown in FIG. 10 is used to perform high-speed feeding).

The feed amount detection circuit 40 detects the film feed amount based on the detection signal of the photo reflector 32. Film winding stop position detection circuit 42
Is equipped with an encoder or the like attached to the rotary fork to which the lower end 17 of the sleeve is mounted, and its actual position is adjusted so that the rotation stop position of the sleeve 16 when the winding of the film 18 is completed matches a predetermined angular position. The winding stop position is detected. Data disk reading circuit 4
4 determines whether the sleeve 16 of the film cartridge 14 is stopped at the rotational position shown in FIGS. 4A to 4C based on the detection signals of the photo reflectors provided at the positions P1 and P2. Together with the sleeve 1
The bar code information (that is, film information) of the disk 20 fixed to the No. 6 is read.

The cartridge loading circuit 45 is provided with a photoreflector of, for example, a reflection type provided in the vicinity of the loading position of the film cartridge 14, and the film cartridge 1
It is to detect whether or not 4 is loaded.

The user information input circuit 46 is set by the user in Table 1.
It is a circuit for inputting arbitrary information (comment, title, etc.) m shown in FIG.

The magnetic signal reading circuit 50 is connected to the magnetic signal reading head 38 and includes an amplifier circuit 51, a filter 52, and a comparator 53 as shown in FIG. In this structure, the signal recorded in the magnetic recording unit 34 is read as a minute voltage by the magnetic signal read head 38, amplified to an appropriate level by the amplifier circuit 51, and noise is cut by the filter 52, and then the comparator. The signal is converted into a logic level signal (digital signal) by 53.

Generally, in a camera, a magnetic signal can be read at a sufficient level due to the presence of an azimuth angle between the film 18 and the head 38, a positional deviation in the film width direction, a change in the film feeding speed, and jitter. Is difficult,
It is possible to determine the presence or absence of recording by detecting the magnitude of the reproduction output. That is, as shown in FIG. 9, if the analog signal is digitally converted in the comparator 53 based on the threshold level Vth, the noise component almost exceeds the threshold level when the magnetic signal is not recorded. Since the output of the comparator 53 does not change to H or L because it does not exist, conversely, when data is recorded, as shown in FIG. 9, the analog signal is moved up or down by the number of times corresponding to the number of bits of data. Since the output of the comparator 53 repeats the inversion of H and L for each bit across the threshold level of, if the number of inversions per frame is more than a predetermined value,
It can be determined that the data is normally recorded in the magnetic recording unit 34.

The microcomputer 60 includes a data setting means 61, a motor control means 62, and a display control means 6
3 and a photographing control means 64.

The data setting means 61 sets the magnetic write data to be written in the magnetic recording section 34 by the magnetic signal writing means including the magnetic signal writing circuit 68 and the magnetic signal writing head 36. A detailed description will be given based on a flowchart described later.

The motor control means 62 controls the feed motor drive circuit 70 as shown in FIG. The feeding motor drive circuit 70 includes an internal power supply 71 and a motor drive unit 72 having four switching transistors. The motor drive unit 72 includes a pair of transistors arranged in diagonal positions with respect to the motor. Since the ON voltage is simultaneously applied from the control means 62, a drive current for forward rotation drive is supplied to the feed motor 13 through these transistors, and the ON voltage is simultaneously applied to the other set of transistors. Thus, a drive current for reverse rotation drive is supplied to the feed motor via these transistors. Here, which group of transistors is to be turned on is determined by the motor control means 62 in accordance with winding and rewinding.

A power supply cartridge 75 containing an external auxiliary power supply 74 having a voltage higher than that of the internal power supply 71 is attached to and detached from the camera. When the power supply cartridge 75 is not attached, the high-speed winding mode is set. The setting switch SW6 is kept off, and when the power supply cartridge 75 is mounted, the high-speed winding mode setting switch SW6 is turned on. When the high-speed winding mode setting switch SW6 is off, the internal power source 71 is connected to the motor driving unit 72 to rotate the feeding motor 13 at the normal speed as shown in FIG. Winding mode setting switch S
When W6 is on, the external auxiliary power supply 74 is connected to the motor drive unit 72 to drive the feeding motor 13 at a higher speed than the normal speed. Further, the motor control means 62
When the silent winding mode switch SW5 is turned on, the feed motor 13 is driven at a low speed by duty control such as PWM control.

Further, even if the film 18 is partially exposed, the motor control means 62 forces the film rewinding operation when the rewinding switch SW7 is turned on, and the state of the film is changed. Accordingly, the film winding stop position is controlled based on the detection signal of the film cartridge winding stop position detection circuit 42. Specifically, in the state where the film 18 has been exposed (that is, the state in which all the frames 28 have been exposed), as shown in FIG. 4C, the bar code of the disc 20 is set at both the positions P1 and P2. The sleeve 16 is stopped at the rotational position where the black portion is detected (that is, the rotational position where the display member 22 indicates the exposed display mark 26 as shown in FIG. 5C), and the film 18 is partially exposed ( That is, in the state in which the rewind is forcibly performed from the state where the exposure is performed only on some of the frames 28),
As shown in FIG. 5B, the rotational position where the white and black portions of the bar code of the disk 20 are detected at the positions P1 and P2 respectively (that is, the display member 22 as shown in FIG. 5B).
Is configured to stop the sleeve 16 at a rotation position indicating the partial exposure display mark 25). Further, the film cartridge 14 is shown in FIG.
As shown in FIG.
The sleeve 16 is set at the rotational position where the white portion of the barcode of 0 is detected (that is, the rotational position where the display member 22 indicates the unexposed display mark 24 as shown in FIG. 5A). Therefore, when the film cartridge 14 is mounted, the film cartridge 14 can be detected by detecting the rotational position of the disc 20.
The state of the film cartridge 14 can be grasped by the user just by looking at the mark indicated by the display member 22.

The display control means 63 causes the display section 80 provided on the surface of the camera 10 to perform various kinds of display, and the photographing control means 64 is based on the set mode.
The exposure circuit 82 is caused to perform an appropriate exposure operation by utilizing the measurement signals of the photometry circuit 47 and the distance measurement circuit 48.

Next, the control operation actually performed in the camera 10 will be described with reference to the flow charts of FIGS.

Step # 5 in FIG. 11: After the reset is started,
The microcomputer 60 initializes I / O and memory. At this time, the winding mode is set to the normal winding mode, and the magnetic write data is set to the data a to g in Table 1 above.

Step # 10: The loading of the film cartridge 14 into the camera 10 is detected.

Step # 15: The rotational position of the disk 20 in the mounted film cartridge 14 is detected, and the film state is determined based on the result. That is, as shown in FIG. 4C, when the black portion of the disk bar code is detected at both the positions P1 and P2, it is determined that the exposure has been completed and the process proceeds to step # 20, as shown in FIG. As described above, when the white portion of the disk barcode is detected at both the positions P1 and P2, it is determined that it is not exposed and the process proceeds to step # 25. Further, as shown in FIG. 7B, when the white portion of the disc barcode is detected at the position P1 and the black portion of the disc barcode is detected at the position P2, it is determined that the film is a partially exposed film and the step is performed. # 3
Go to 0.

Step # 20: Since all the frames 28 of the film 18 in the mounted film cartridge 14 have been exposed, the display section 80 displays a warning indicating that the film has been exposed, and step # 205 (cartridge removal; FIG. 13), which will be described later, is performed. Proceed to.

Step # 25: Since the mounted film cartridge 14 has not been exposed, a normal initial load (initial setting) is performed and the film 18 is sent to the photographing position of the first frame. The procedure is as shown in FIG. That is, after displaying the unexposed film on the display unit 80 (step # 250), the feeding motor 13 is rotated in the forward direction to feed the film 18 out of the film cartridge 14 (step # 255). Then, the feeding amount detection circuit 4
When the photographing position of the first frame is detected by 0 (step # 260), the feeding motor 13 is stopped (step # 265), and the display unit 80 displays that the preparation for photographing is completed (step # 270). .

Step # 30: Since the mounted film cartridge 14 is partially exposed, the exposed frame is skipped and the film 18 is fed to the unexposed frame position. The procedure is as shown in FIG. First, after displaying that the film is partially exposed (step # 300), the feeding motor 13 is rotated in the forward direction to feed the film 18 out of the film cartridge 14 (step # 305), during which feeding detection is performed. While the circuit 40 detects the position of each frame 28, the number of times the digital signal output from the magnetic signal reading circuit 50 is inverted (that is, the number of bits of data) is counted (step # 310). Then, it is determined whether or not the number of bits of each frame 28 is greater than or equal to a predetermined number, and when a frame having a predetermined number or more, that is, an unexposed frame in which no data is written is found (NO in step # 315), feeding is performed. The motor 13 is stopped (step # 320), and the shooting preparation completion display is displayed (step # 325). In addition, without finding an unexposed frame (YES in step # 315).
If the final frame has been reached (step # 3
(YES in 30), which means that there is no unexposed frame after all, so the feeding motor 13 is stopped to display the exposed state (step # 340), and the film 18 is rewound to rewind.
2 to step # 195.

Step # 35: The winding mode is set here. The procedure is as shown in the flowchart of FIG.

In step # 350 of the figure, when the multiple exposure mode setting switch SW4 is turned on, the exposure mode is set to the multiple exposure mode (step # 35).
5). In this mode, first, the initial value "2" is set in the exposure counter (step # 360), and the multiple exposure number is set to the number of times the multiple exposure number setting switch SW3 is turned on. That is, the multiple exposure number setting switch SW3
If the switch SW3 is turned on (YES in step # 365), the switch SW3 is turned off next (step # 365).
(OFF at 370) The exposure counter is incremented by 1 (step # 375), and after a certain period of time elapses (step # 375).
380) It is confirmed again whether the switch SW3 is on or off (step # 385), and if it is on, the above step # 370 is performed.
Repeat from.

If it is off, it is determined that the exposure number setting operation has been completed, and then it is determined whether the switches SW5 and SW6 are on or off. Specifically, when the silent winding mode setting switch SW5 is on (ON at step # 390), the silent winding mode is set as the winding mode (step # 395), and the silent winding mode setting switch SW5 is off (step # 395). OF in # 390
F) and when the high-speed winding mode setting switch SW6 is on (ON in step # 400), the high-speed winding mode is set (step # 410). Both switches SW
If 5 and SW6 are off, the normal mode is set (step # 405).

Although not shown in the flow chart, when any one of the multiple exposure mode, the high-speed winding mode, and the silent winding mode is set, normal data is not written in the magnetic recording unit 34, so that the display is performed. Part 8
0 causes the warning display to that effect.

Step # 40: Here, user information is set. The procedure is as shown in the flowchart of FIG. In the figure, if there is an information setting request (YES in step # 500), it is determined whether the requested information is arbitrary information (information arbitrarily set by the user) (step # 500). 505) If it is not the arbitrary information, the data a and b of the data shown in Table 1 and the data selected by the user from the data c to l are set as the magnetic writing data (step # 510). In the case of arbitrary information, a comment or the like is input as this arbitrary information (step # 515), and the input arbitrary information and data a and b are set as magnetic write data (step # 520). Step # 5
If there is no information setting request in 00, the data a set in advance as the specific information among the data shown in Table 1
To g are set as magnetic write data (step # 5
25).

Of the data in Table 1, a. Print size and b. Since the top-and-bottom information is necessary for printing in the laboratory, it is always written in any of steps # 510, 520, and 525.

Step # 45: It is determined whether the rewind switch SW7 is on or off, and if the rewind switch SW7 is on (that is, there is a rewind request), step # 45.
At 46, a partial exposure state is set (step # 46), and rewinding is performed (step # 150). Rewind switch SW
If 7 is off, the process proceeds to step # 50.

Step # 50: Shooting preparation switch SW1
To determine. When the switch SW1 is on, photometry and distance measurement are performed (steps # 55 and # 60), and the release switch SW2 is determined (step # 65). If the release switch SW2 is off, the operation from step # 50 is repeated, and if the switch SW2 is on, exposure is performed (step # 70).

Step # 75: After the exposure is completed, the exposure mode is determined. In the multiple exposure mode, the exposure counter is decremented by 1 (step # 80), and the operation from step # 45 is repeated until the exposure counter becomes 0 (step # 85 ≠ 0). When the exposure counter reaches 0, the print inhibition data is set as the magnetic write data instead of the data c to l shown in Table 1 (step # 90). This print prohibition data is
This is data for instructing the prohibition of data printing at the time of printing out on photographic paper, and by reading this data at the time of development in the laboratory, printing relating to this data is blocked. The print prohibition data is not set for the arbitrary information m regardless of whether the multiple exposure mode is set or not, and the arbitrary information m is printed as it is.

Step # 95 in FIG. 12: After the exposure, the winding mode is determined. When the winding mode is the normal mode (YES in step # 95), the data specified so far is set as the magnetic writing data as it is (step # 100), but the special mode other than the normal mode (silent winding mode or In the high speed winding mode) (NO in step # 95), magnetic write data is set to data in which all bits are "1" (all bits may be "0") (step # 105). In the case of high-speed winding mode, such meaningless data is input because the speed is so fast that the reliability of the written data cannot be guaranteed from the aspect of writing responsiveness, etc. In the winding mode, speed fluctuation and jitter are likely to be large because low-speed feeding is performed by PWM, etc., and the reliability of the data is not good, so erroneous processing may be performed on such unreliable data. This is to prevent it. Further, by writing meaningless data instead of stopping the writing of the data, the frame 28 in which this data is written in the magnetic recording section 34 is written.
It is possible to determine that the film has already been exposed when the film is wound.

Steps # 110 to # 145: This shows the winding control operation. After starting winding (Step # 1
10) In the silent winding mode (step # 1
YES in 15) Duty control of the feeding motor 13 (PW
It is driven at a low speed by M control or the like), and in other modes (NO in step # 115), the feeding motor 13 is continuously energized and driven at a predetermined speed. While performing the winding operation as described above, the step # 100 or the step # 105 is performed.
The magnetic write data set by the magnetic write head 36
Is written in the magnetic recording section 34 (step # 13).
0), when the predetermined amount (that is, one frame) is fed (YES in step # 135), the feeding motor 13 is stopped (step # 140). If the final frame is wound up (YES in step # 145), the rewinding sequence is started from step # 195. If it is not the final frame (NO in step # 145), the step # 50 in FIG. The subsequent operations are repeated.

Rewinding operation: After the final frame is reached, the feeding motor 13 is rotated in the reverse direction to start rewinding (step # 19).
5), winding up the entire film 18 (step # 20
0), based on the angular position (film winding position) detected by the film winding stop position detection circuit 42 at this time, the feeding motor 13 is set to the exposed position (that is, the state where the disk 20 is in the state shown in FIG. 4C). Is stopped (step # 185 in FIG. 13). Thereafter, the rewind completion display is displayed (step # 190), and the process waits for the film cartridge 14 to be taken out (step # 205).

Steps # 150 to # 19 of FIGS.
0: These indicate the sequence of midway rewinding.
First, after the feeding motor 13 is rotated in the reverse direction to start rewinding (step # 150 in FIG. 11), the magnetic signal is read in each frame as in step # 310 (step # 15).
5) If the data is normally written in all the frames 28 (YES in step # 160), that is, if the number of bits having the output of the predetermined level or more is equal to or more than the predetermined number in each frame 28, the same as it is. Step # 1
If the data is not normally written in any of the frames 28, that is, if the number of bits having an output equal to or higher than the predetermined level is less than the predetermined number (NO in step # 160), the process proceeds to 70. The film state is set to the exposed state despite the return (step # 1)
65). By doing so, it is possible to prevent the above-described inconvenience that a frame in which data is not normally written is erroneously detected as an unexposed frame and is double-exposed when the next use is started.

After that, when the film 18 is completely wound (YES in step # 170 of FIG. 13), the film state is determined (step # 175), and when the film state is partially exposed, the film is wound. Stop position detection circuit 4
2 is used to stop the feeding motor 13 at the partially exposed position (position in FIG. 4B) (step # 18).
0), in the exposed state, the feeding motor 13 is stopped at the exposed position (position in FIG. 4C) (step # 18).
5). Then, display the completion of winding (step # 1
90) and waits for the film cartridge 14 to be taken out (step # 205).

As described above, in the camera 10, the special winding mode such as the high-speed winding mode or the silent winding mode, that is, the mode in which the film winding speed is inappropriate for magnetic recording and inaccurate data may be written. In this case, since fixed special meaningless preset special data is set as the magnetic writing data regardless of the exposure state of the frame 28, it is possible to surely cause unnecessary confusion due to the incorrect writing of the data. Can be prevented. The confusion can be avoided even when no data is written in the special winding mode, but in this case, the frame 28 in which no data is written is erroneously detected as an unexposed frame. On the other hand, if special data is written as in the above-described embodiment, the frame 28 will not be erroneously detected as an unexposed frame.

In this embodiment, the special winding mode has both the high-speed winding mode and the silent winding mode (that is, the low-speed winding mode), but in the present invention, either one of the special winding modes is used. It is also applicable to cameras equipped with.

[0056]

As described above, according to the present invention, in a camera having a magnetic recording function, the film winding mode can be switched between a normal winding mode and a special winding mode, and at the time of winding in the special winding mode. Since the preset special data is written regardless of the exposure state of the frame, it is possible to avoid troubles and unnecessary confusion due to incorrect data being written in the special winding mode. There is an effect that the reliability of other data can be kept high. Also,
In the special winding mode, unlike the case where the data writing itself is prohibited, the above-mentioned data writing prohibited frame is not erroneously detected as an unexposed frame during the next use, and double exposure is erroneously performed from this frame. Can be surely prevented.

[Brief description of drawings]

FIG. 1 is a block diagram showing a functional configuration of a microcomputer equipped in a camera according to an embodiment of the present invention.

FIG. 2 is a schematic perspective view showing an internal structure of the camera.

FIG. 3 is a sectional front view of a film cartridge mounted on the camera.

FIG. 4A is a bottom view showing a state where the disc in the film cartridge is in an unexposed position, and FIG. 4B is a bottom view showing a state in which the disc is partially exposed.
(C) is a bottom view showing a state where the disc is in an exposed position.

5A is a plan view showing a state in which the display member in the film cartridge indicates an unexposed display mark, and FIG. 5B shows a state in which the display member indicates a partially exposed display mark. FIG. 3C is a plan view showing a state in which the display member indicates the exposed display mark.

FIG. 6 is a front view showing a state of the film pulled out from the film cartridge.

FIG. 7 is an enlarged front view of the film.

FIG. 8 is a block diagram showing a magnetic signal reading circuit provided in the camera.

FIG. 9 is a graph showing signal processing contents of a comparator in the magnetic signal reading circuit.

FIG. 10 is a diagram showing a feed motor drive circuit provided in the camera.

FIG. 11 is a flowchart showing a control operation performed in the camera.

FIG. 12 is a flowchart showing a control operation performed in the camera.

FIG. 13 is a flowchart showing a control operation performed in the camera.

FIG. 14 is a flowchart showing a control operation performed in the camera.

FIG. 15 is a flowchart showing a control operation performed in the camera.

FIG. 16 is a flowchart showing a control operation performed in the camera.

FIG. 17 is a flowchart showing a control operation performed in the camera.

[Explanation of symbols]

10 Camera 13 Feed Motor (Film Feeding Means) 14 Film Cartridge 18 Film 28 Frame 34 Magnetic Recording Section 36 Magnetic Writing Head (Magnetic Writing Means) 60 Microcomputer 61 Data Setting Means 62 Motor Control Means 68 Magnetic Signal Writing Circuits (Magnetic) Writing means) 70 Feed motor drive circuit (film feeding means) SW5 Silent winding mode setting switch (winding mode switching means) SW6 High speed winding mode setting switch (winding mode switching means)

Claims (1)

[Claims] 1. In a camera equipped with a film having a magnetic recording portion and having a magnetic recording function for recording data in the magnetic recording portion in accordance with the exposure state of each frame of the film, winding of the film. And a film feeding means for rewinding, a magnetic signal writing means for recording data corresponding to each frame in the magnetic recording portion when the film is wound, and magnetic writing data written by the magnetic signal writing means in the magnetic recording portion. Data winding means for setting the film winding mode by the film feeding means and a normal winding mode for winding the film at the normal winding speed capable of normal data writing by the magnetic signal writing means and a speed different from the normal winding speed. And a winding mode switching means for switching to a special winding mode for winding the film, The magnetic recording function is characterized in that the data setting means is configured to set, as the magnetic writing data, certain special data set in advance regardless of the exposure state of the frame when winding in the special winding mode. A camera.