JPH10104728A - Camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To guarantee that proper preparations for photographing can be made, when a film cartridge taken out halfway is loaded and to prevent a failure such as double exposure by inhibiting the use of the film cartridge taken out halfway, when the above-mentioned guarantee is not obtained. SOLUTION: At the time of executing magnetic recording, a microcomputer 2 transmits a recording signal to a recording/reproducing circuit 15 and this circuit 15 reverses a magnetic field generated by a magnetic head 12, based on the recording signal. Further, the microcomputer 2 reads data on a reproducing signal, in synchronization with an encoding pulse, at the time of magnetic reproducing. When the film cartridge taken out halfway is loaded, a threshold for a battery check is increased. When the battery check is permitted, preparations for photographing for the film cartridge 8 taken out halfway are made possible. On the other hand, when the battery check is not permitted, the use of the film cartridge 8 taken out halfway is inhibited.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a camera, and more particularly to a camera, in which a film cartridge having an exposed frame and an unexposed frame stored in a film cartridge and taken out in the middle thereof can be loaded. The present invention relates to a camera capable of performing re-photographing.

[0002]

2. Description of the Related Art In recent years, a new photographic film in which a magnetic layer is formed on one side of a silver halide film has been proposed (USP5).
No. 130745), a film cartridge for accommodating the film, and a camera for photographing using the film cartridge have also been developed, and have been standardized worldwide.

As shown in FIGS. 21A and 21B, in a cartridge roll film 100 of a new standard, a film 103 wound around a spool 102 is housed in a substantially cylindrical cartridge case 101 having a light shielding structure. In addition, a light-shielding cover 104 is provided at one end of the cartridge case 101, and when the camera is not loaded or taken out of the camera, the film 103 is always completely stored in the cartridge case 101, and the light-shielding cover 104 The structure protects from external light.

At the side end of the cartridge case 101, a data disk 105 which rotates together with the spool 102 is provided.
Is provided on the outer surface of the data disk 105.
A bar code indicating film information such as the type of the film 103, the film sensitivity, and the number of frames that can be shot is printed in advance. Further, the other side end of the cartridge case 101 has holes 111, 11 of circles, squares, crosses, and half moons.
2, 113 and 114 are bored, and a white tongue (not shown) that rotates integrally with the spool 102 is provided on the back side of these holes, and according to the stop position of the tongue. , A circle, a square, a cross, and a half moon are displayed in a so-called outline.

[0005] The white circles indicate the cartridge case 10.
Indicates that the film in 1 is unexposed (unexpose)
, A white square indicates that the film has been developed, a white cross indicates that the film has been exposed and has not been developed (expose), and a white half-moon indicates that the film has not been exposed. Is defined as a partial that indicates that there is a residual. This outline display is VEI (visual exp
It is called “osure index”, and you can check the usage of the film by looking at these displays from the outside.

In the film 103, a silver salt photosensitive layer is applied to the front surface 103F of the film base, and a magnetic recording layer is applied to the back surface 103R. Also, film 103
A plurality of perforations 121, 121... That define the range of each photographing frame 120 are formed at the edge of the magnetic recording areas 124, 125 at the upper and lower ends of each photographing frame. It is possible to magnetically record distance, other shooting information, and information of a user message such as a photo title.

When a cartridge film having such a structure is loaded into a camera, an optical reading mechanism in the camera reads bar code information on a data disk 105, and
By detecting the position of the tongue piece, the film information and the usage information are automatically recognized. In the case of a cartridge film in which unused or unexposed frames remain, the light shielding cover 104 is opened and the spool 102 is opened. By rotating the film 103 in a predetermined direction, the film 103 is automatically fed up to the first photographing frame.

When photographing is completed for all photographing frames of the film 103, a rewind mechanism in the camera winds the film 103 into the cartridge case 101, closes the light shielding cover 104, and furthermore,
By stopping the tongue piece, which is integrally fixed to the hole, facing the cross-marked hole, the exposed white display (cross-mark) is performed.

When a rewind operation is forcibly performed in the middle of photographing with unexposed frames remaining, a rewind mechanism in the camera winds the film 103 into the cartridge case 101, closes the light shielding cover 104, Further, by stopping the tongue piece integrally fixed to the spool 102 so as to face the hole of the half moon mark, a white display indicating that unexposed frames remain is displayed.

On the other hand, if the loaded cartridge has been exposed or developed, it is determined that photographing is impossible, and processing such as not performing the automatic feeding is performed. In such a camera, the film cartridge can be taken out of the camera by forcibly rewinding the film while the unexposed frames remain (hereinafter, this film cartridge is referred to as a film cartridge taken out in the middle), and the film taken out in the middle is taken out. When the cartridge is reloaded into the camera, the information on the magnetic recording layer is read by the magnetic head in the camera, and the film is fed to a portion where no magnetic information is recorded, so that re-photographing from an unexposed frame can be performed. It has become.

[0011]

However, a camera which can use a film cartridge which has been taken out halfway, has a problem in that when a film cartridge which has been taken out halfway is loaded into the camera, it is necessary to determine whether an exposed frame or an unexposed frame has been detected or not. The photographic film must be fed up to the unexposed frame, and a large amount of power is required in preparation for photographing. In particular, when judging an exposed frame and an unexposed frame based on magnetic information recorded on a magnetic recording layer of a photographic film,
It is necessary to feed the photo film at a predetermined speed.For example, if the feed speed of the photo film fluctuates or decreases due to the exhaustion of the battery in the camera, it becomes impossible to determine the exposed frame and the unexposed frame. There is a problem that it is not possible to prepare for taking out the film cartridge to be taken out.

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and assures that appropriate preparation for photographing can be performed when a film cartridge which is to be taken out halfway is loaded. It is an object of the present invention to provide a camera capable of prohibiting the use of a film cartridge.

[0013]

According to the present invention, in order to attain the above object, a film cartridge loaded in a camera has a photographic film having an exposed frame and an unexposed frame stored in the film cartridge. It is determined whether or not the film cartridge has been taken out halfway, and if it is determined that the film cartridge has been taken out halfway, the camera battery for feeding the photographic film from the film cartridge to the first unexposed frame. For proper shooting with proper voltage
First determining means for determining whether or not the film cartridge is not less than the threshold value, and determining that the film cartridge loaded in the camera is not the film cartridge taken out halfway,
When the voltage of the battery in the camera is determined to be equal to or less than the first threshold value by the first determination means, a first battery check means including first prohibition means for prohibiting photographing; Second determining means for determining whether or not the voltage is equal to or higher than a second threshold value higher than the first threshold value; and determining that the film cartridge loaded in the camera is the film cartridge taken out halfway; and A second battery check unit comprising: a second prohibition unit for prohibiting photographing when the voltage of the battery in the camera is determined to be equal to or less than the second threshold value by the second determination unit;
It is characterized by having. That is, when a half-loaded film cartridge is loaded, the threshold value of the battery check is increased, and when the battery check is permitted, the shooting preparation for the half-loaded film cartridge is ensured. In the case where is not permitted, use of a film cartridge taken out halfway is prohibited so that a problem such as re-exposure of an exposure frame by mistake is prevented.

Further, according to the present invention, it is determined whether or not a film cartridge loaded in a camera is a film cartridge which is taken out halfway where a photographic film having an exposed frame and an unexposed frame is stored in the film cartridge. If the film cartridge is determined to be a film cartridge that has been taken out halfway, in a camera that feeds the photographic film from the film cartridge to the first unexposed frame, the temperature inside the camera is detected, and the detected temperature is used as the temperature. First determining means for performing a first determination indicating that the temperature is equal to or lower than a predetermined reference temperature which affects the feeding speed of the photographic film, detecting a type of a film cartridge loaded in the camera, and detecting the detected film A second format indicating that the cartridge contains a reversal film. A second determining means for detecting the feeding speed of the photographic film, and a third determining means for performing a third determination indicating that the detected feeding speed is equal to or less than a predetermined speed. And either the voltage of the battery in the camera when feeding the photo film is lower than a predetermined reference voltage or the motor current for feeding the photo film is higher than a predetermined reference current. 1 or 2 of the fourth determination means for performing the fourth determination indicating
The above determination means and the determination means perform one or more of the first to fourth determinations, and determine that the film cartridge loaded in the camera is the film cartridge taken out halfway. Then, prohibiting means for prohibiting photographing using the film cartridge taken out halfway is provided. That is, if a film cartridge that has been taken out halfway is loaded and one or more of the first to fourth determinations are made, there is a risk that good shooting preparation for the film cartridge that has been taken out halfway cannot be made. Therefore, in this case, the use of the film cartridge taken out halfway cannot be performed.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the camera according to the present invention will be described below in detail with reference to the accompanying drawings. FIG.
1 shows a configuration of a camera according to an embodiment of the present invention. This camera uses the new standard cartridge roll film shown in FIG. 21. Each time shooting is completed, a winding command is input from the microcomputer 2 to the motor driver 3, and the motor 5 built in the spool 4 is turned on. Driven. By the rotation of the motor 5, the spool 4 rotates in the film winding direction via the drive transmission mechanism 6, and the feeding of the photographic film 7 is started. As a result, the photo film is pulled out from the cartridge 8,
It is wound on the spool 4.

The drive transmission mechanism 6 can also rotate the spool 8a of the cartridge 8. Immediately after the cartridge 8 is loaded, the drive transmission mechanism 6 drives the spool 8a in the direction in which the film is sent out to move the photographic film 7 to the leading end. Send out from. Thereafter, when the leading end of the photographic film 7 winds around the spool 4 and the rotation of the spool 4 causes the photographic film 7 to be fed at a speed higher than the sending speed by the rotation of the spool 8a on the cartridge 8 side, the cartridge The spool 8a on the side 8 rotates following the feeding of the film.

In this manner, the film leader is
When the first frame is sent to the shooting position, the motor 5 stops. At the time of rewinding, the motor 5 rotates in the reverse direction to drive the spool 8a on the cartridge 8 side in the film winding direction, and the spool 4 is driven to rotate. Then, the photo film 7 is completely wound into the cartridge 8 up to the leading end.

In the photographic film 7, two perforations 7a and 7b are formed for each frame. In particular, for the first frame, one more perforation is provided on the leading end side of the film with respect to the perforation 7a. A reflection type photo sensor 9 faces the pass band of these perforations.
Is input to the PF pulse generator 10.
The PF pulse generator 10 outputs a pulse signal every time the perforations 7a and 7b pass through the front surface of the photo sensor 9. This pulse signal is input to the microcomputer 2.

After receiving the photographing completion signal, the microcomputer 2 drives the motor 5 via the motor driver 3 to start film feeding. Then, when the photo sensor 9 detects the perforation 7a on the leading side of the film, the feeding of the film is stopped and the feeding of one frame of the film is completed. A transparent magnetic recording layer is formed on the entire back surface of the photographic film 7, and the magnetic head 12 is driven during the period in which one frame of the film is being fed. Exposure information and the like are magnetically recorded in a predetermined magnetic recording area 11 for each photographic frame. When recording this information, all characters and numbers that constitute the information are 2
The binary code is converted into a value code and digitally recorded.

The recording / reproducing circuit 15 generates data pulses having different duty ratios in accordance with a recording signal supplied from the microcomputer 2 during recording. Based on this data pulse, magnetic recording is performed by the magnetic head 12 in the form of binary codes “1” and “0”. When performing this magnetic recording, the encoder 16 and the ENC pulse generator 17 are used so that the unit bit length does not change under the influence of the film feeding speed. The encoder 16 is composed of an encoding plate 16a in which slits are formed radially at a constant pitch on a disk that rotates following the feeding of the photographic film 7, and a photo interrupter 16b that photoelectrically detects the passage of the slits.
A photo-electric signal that fluctuates in synchronization with the feeding speed of the photo film 7 is output from the photo interrupter 16b. This photoelectric signal is shaped by the ENC pulse generator 17 and input to the microcomputer 2 as an encode pulse synchronized with the film feeding speed. For example, the encoding plate 1
One rotation of 6a generates 256 encode pulses. The encoding plate 16a rotates three times during the feeding of one frame of film.

At the time of magnetic recording, the microcomputer 2
Sends a recording signal to the recording / reproducing circuit 15 while monitoring the interval of the encode pulse,
Reverses the magnetic field generated by the magnetic head 12 at a timing corresponding to the binary code "1" or "0" in the unit bit length of the magnetic recording based on the recording signal. Also,
The microcomputer 2 reads data of a reproduction signal from an A / D port in synchronization with the encode pulse during magnetic reproduction.

Incidentally, the configuration of the encoder is not limited to the above.
The encoding plate may be attached to the shaft of the feeding motor 5, and the passage of a large number of slits formed on the encoding plate may be detected by a photo interrupter. FIG.
Has a ROM area and a RAM area, and the ROM area stores a sequence program for executing the magnetic recording described above or reading magnetic information from the magnetic recording area 11. Along with
Data and the like for converting information to be magnetically recorded into a binary code are stored.

The RAM area is used for temporarily storing data and flags when performing a magnetic recording / reproducing process. The method of magnetic recording and the reproduction process will be further described later (FIGS. 3 and 11). FIG. 2 shows an example of the configuration of the magnetic head 12. The magnetic head 12 has a single core 1
3 is formed by winding a single coil 14 for 300 turns, and both terminals 14a and 14b of the coil 14 are used for recording and reproduction as they are.

In the magnetic head 12 shown in FIG. 1, a single coil 14 is wound around a single core 13 and the magnetic head is shared for recording and reproduction. There is an advantage that no induced current occurs. Also, by setting the number of turns of the coil 14 to 300, there is an advantage that the magnetic head can be made smaller (thinner) and lower in cost.

FIG. 3 shows an example of a magnetic recording pattern. In the figure, and indicate the switching timing of the terminal potentials of the terminals 14a and 14b of the coil 14 shown in FIG. 2, respectively, and I _H in the figure indicates the direction of the recording current flowing through the coil 14. When the terminal 14a of the coil 14 is at a high level and the terminal 14b is at a low level, the recording current I _H flows in the direction of the arrow (positive direction) in FIG. 2 and the “N magnetization region” (recording pattern in FIG. The area in which the lines of magnetic force are shown rightward is recorded. Conversely, terminal 14
When a is at a low level and the terminal 14b is at a high level, the recording current I _H flows in the opposite direction (minus direction) to the arrow in FIG. 2, and the “S magnetization region” (in the recording pattern in FIG. , The magnetic field lines are shown facing left).

One recording period T for determining the unit bit length of the magnetic recording is determined by a period in which the terminal 14a rises to a high level, and the pulse width TD of the data pulse for determining the binary code "1" or "0" is "1". It depends on whether the end of the “N magnetization region” is located in the first half of one recording cycle T or in the second half. When the binary code "1" is recorded, the pulse width TD .gtoreq.T / 2, and when the binary code "0" is recorded, the pulse width TD <T / 2. Is input with a recording signal.

FIG. 4 shows a configuration example of the recording / reproducing circuit 15. The recording / reproducing circuit 15 mainly includes a power supply circuit 15a, a reproducing circuit 15b, and a recording circuit 15c as surrounded by a broken line. The power supply circuit 15a includes a battery 20, which is also used as a power supply for opening and closing the shutter blades and feeding the film at the time of photographing. For example, a 3V lithium battery is used as the battery 20. Then, a voltage of 5 V is obtained by the booster circuit 21, and voltages of 5 V and 4.1 V are obtained by the regulator 22.
3, a voltage of 2.3 V can be obtained.

The output port of the regulator 23 includes:
A switching transistor 24 is connected,
The base terminal is connected to the MRCON port of the camera CPU (corresponding to the microcomputer 2 shown in FIG. 1). If it is confirmed that unexposed frames remain in the loaded film cartridge 8, this MRCO
When a low level (L) signal is output from the N port and the base terminal of the transistor 24 is at the ground potential, a reference voltage of 2.3 V is supplied to the amplifier circuit 30 of the reproducing circuit 15b. The two capacitors 25 and 26 included in the power supply circuit 15a are connected to the reference voltage 2.
This prevents high frequency noise from being applied to 3V.

The reproducing circuit 15b includes the magnetic head 12, an amplifier 30, a smoothing circuit 32, and a low-pass filter 33. The amplifier circuit 30 includes a resistor 35 for converting a reproduction current flowing through the coil of the magnetic head 12 into a reproduction signal.
And operational amplifiers 36, 37 and 38 for non-inverting and amplifying the signal voltage obtained from the resistor 35. As each of the operational amplifiers 36, 37, and 38, a general commercial product can be used, and it is preferable to use one in which a protection resistor is incorporated in an input stage for preventing electrostatic breakdown.

The amplifying circuit 30 includes an operational amplifier 3
A feedback circuit and a capacitor for cutting high-frequency noise are provided alongside 6, 37, and 38. Note that in FIG.
Although the signal voltage is amplified in three stages using one operational amplifier, the configuration of the amplifier circuit 30 is not limited to this.
The power supply lines of the operational amplifiers 36, 37, 38
5V from output port (VOF port) of regulator 22
, And a reference voltage (2.3 V) is led from the output port of the regulator 23 to the inverting input terminal of each of the operational amplifiers 36, 37, and 38.
That is, the amplifying circuit 30 is driven by three types of voltages: the driving voltages “+ Vcc (5V)” and “−Vcc (GND)” from the regulator 22 and the reference voltage (2.3 V) from the regulator 23. Has become. By using two regulators, as shown in FIG.
There is also an advantage that the ground of the operational amplifier can be stabilized.

The regulator 22 that supplies a drive voltage to the amplifier circuit 30 is controlled based on a command signal from the camera CPU, and operates in accordance with the command signal.
At 38, the drive voltage is supplied / cut off. Specifically, the drive voltage is supplied during the film feed command period, and the drive voltage is cut off during the film stop period. When the drive voltage is not supplied, the amplifier circuit 30 becomes inoperable. However, when a signal voltage at the time of writing (at the time of recording) is input to the non-operating operational amplifiers 36, 37, and 38, the operational amplifiers 36, 3
The drive voltage is always supplied to the amplifier circuit 30 at the time of recording because there is a risk that the devices 7 and 38 may fail.
Since the motor 5 is always driven during magnetic recording, a driving voltage is supplied to the amplifier circuit 30 when the motor 5 is driven.

As described above, when reproducing (reading) magnetic information.
In addition, by supplying a drive voltage (5 V) to the amplifier circuit 30 also during recording (writing) of magnetic information, the operational amplifiers 36 and 37 in which the reference voltage from the regulator 23 is not supplied to the non-inverting input terminal. , 38 are used as comparators, and the operational amplifiers 36, 37, 3
8 are protected.

The smoothing circuit 32 following the amplifier circuit 30 is composed of a diode 40, a capacitor 41 and a resistor 42, and smoothes the electric signal amplified by the amplifier circuit 32. In order to recognize the position of the unexposed frame from the magnetic information recorded on the magnetic recording layer on the photographic film 7, it is sufficient to determine whether or not the magnetic information is recorded on the magnetic recording layer and whether or not the magnetic information is recorded. There is no need to accurately read the contents of the information, that is, the binary codes "1" and "0". From this viewpoint, the signal amplified by the amplifier circuit 30 is smoothed, and the presence or absence of recording of magnetic information is determined based on the envelope waveform.

At this time, the signal obtained via the magnetic head 12 includes a noise component of the film feeding motor 5. The AC component of the motor noise appears on either the plus side or the minus side depending on the arrangement relationship between the motor 5 and the magnetic head 12. Focusing on this point, in FIG. 4, the direction of the diode 40 of the smoothing circuit 32 is set so that the AC component of the motor 5 is arranged so as to appear on the plus side, and the AC component of the motor noise is removed. Only the negative area (one side) is taken out.

The noise superimposed on the signal may be caused by unevenness in the feeding speed of the film other than the noise of the motor 5. The higher the feed speed of the photographic film 7, the higher the signal output, and the lower the feed speed, the lower the signal output. Therefore, when a feeding load is applied such as when the film becomes old or hard, the fluctuation of the feeding speed appears as a fluctuation of the signal output. A low-pass filter 33 is provided following the smoothing circuit 32 for the purpose of removing noise caused by such film feeding unevenness.

The low-pass filter 33 includes a resistor 44 and a capacitor 45, and a cutoff frequency can be set by a combination of the two. For example, by forming a low-pass filter having a low frequency of about 16 Hz, fluctuations in the film feeding speed can be absorbed. The reproduced signal that has passed through the low-pass filter 33 is supplied to the microcomputer 2 by A
/ D port (MRCIN). The microcomputer 2 determines the presence or absence of magnetic recording based on the reproduced signal. The method of determination will be described later (FIG. 2
0).

Next, the timing of reading magnetic information will be described. Reading of a reproduction signal added to the A / D port (MRCIN) of the microcomputer 2
This is performed in synchronization with the encode pulse based on the encoder 16. At this time, after detecting the edge of the perforation 7a, the number of pulses from the encoder 16 is counted for a predetermined amount, for example, 256 pulses, and the 256 data is skipped. Start reading.

In the magnetic recording area 11 for each photographing frame,
Focusing on the possibility that magnetic information is recorded in the area near the center between the perforations 7a and 7b, the magnetic recording area 11 of each frame has a predetermined amount (256
The reading (measurement) is performed 256 times after skipping the pulses for the book. Then, the signal level is determined based on the average or integration of the 256 read data. In this way, by limiting the reading of magnetic information for detecting the presence or absence of magnetic recording to the area, the presence or absence of magnetic information can be reliably detected.

Before reading the magnetic information of each photographed frame, the reference data is also acquired 256 times, and the same processing is performed based on the average or integration. When the encoder 16 is mounted on the shaft of the feeding motor 5, reference data can be obtained immediately after the motor 5 is driven and before the photographic film 7 contacts the magnetic head 12.

Next, the recording circuit 15c of the recording / reproducing circuit 15
Will be described. An amplification circuit 15b is provided in the magnetic head 12.
The recording circuit 15c is connected in parallel with the above, so that magnetic information can be written on the magnetic recording layer of the photographic film 7 while feeding the photographic film 7. The recording circuit 15c controls the direction of the recording current flowing through the coil of the magnetic head 12 to perform magnetic recording. The magnetic head 12 is driven by switching transistors 50, 51, 52, 53 which are bridge-coupled, and these switching transistors 50, 51, 52, 53
Is controlled by control transistors 54 and 55.

The base terminals of the control transistors 54 and 55 are respectively connected to the MHC port of the microcomputer 2 and
Connected to MHD port, MHC during magnetic recording
When the high / low signal is applied to the port and the MHD port, the control transistors 54 and 55 are turned on / off, respectively. The base terminal of the switching transistor 50 of the recording circuit 15c is connected to a resistor 58.
Is connected to the output port (VAF port) of the regulator 22 via the. By forming the pull-up circuit in this manner, the operation of the switching transistor 50 is stabilized.

If this pull-up circuit is not provided,
There is a disadvantage that the base and the collector of the switching transistor 50 become free and become unstable in operation. That is, during reproduction, both the MHC port and the MHD port are at a low level, but a voltage of 3 V is applied to the emitter of the switching transistor 50 from the battery 20, and a small current flows between the emitter and collector of the switching transistor 50 due to noise or the like. Flows, current is taken out of the battery 20. There is a problem that this is amplified by the amplifier circuit 30 and is superimposed on the reproduced signal of the current generated in the magnetic head 12. For example, even if the current generated on the recording circuit 15c side at the time of reproduction is as small as about nano-order, it is amplified to about the signal level by the operation of the amplifier circuit 30.

Therefore, at the time of reproduction, it is necessary to completely block the intrusion of current from the recording circuit 15c side. Therefore, the pull-up circuit is provided at the base terminal of the switching transistor 50 so that the regulator 23 applies a potential to the base of the switching transistor 50 when the film is fed. The switching transistor 51 on the left side in the figure does not become unstable since the reference potential of 2.3 V is supplied to the collector terminal at the time of reproduction, and therefore does not need to be pulled up.

Next, the operation of the recording circuit 15c during recording will be described. The clock pulse and data pulse from the microcomputer 2 cause the MHC port and M
The HD port is oppositely switched between high level and low level, and the switching transistors 54 and 55 are selectively turned on / off. For example, when the switching transistor 54 is turned on and the switching transistor 55 is turned off, the control transistors 50 and 53 are turned on, and the recording current I _H flows through the coil 14 of the magnetic head 12 in the direction of the arrow in FIG. The “N magnetization region” is recorded in the recording region 11. Conversely, when the switching transistor 54 is turned off and the switching transistor 55 is turned on, the control transistors 51 and 52 are turned on, and the recording current I _H flows through the coil 14 in the direction opposite to the arrow in FIG. Recording of the “S magnetization region” is performed.

The magnitude of the recording current I _H flowing through the coil 14 depends on the voltage of the battery 20 which is the driving voltage and the resistance 60
(Or the resistance 61) and the resistance of the coil 14. The linear resistance of the coil 14 of the magnetic head 12 shown in FIG. 4 is on the order of several tens of ohms, which is considerably smaller than that on the order of several hundred ohms used for magnetic heads of general audio equipment. .

Protective resistors 60 and 61 are connected to the coil 14 in series according to the direction of the current to prevent an excessive current from flowing through the coil 14 during recording and reproduction. The wire diameter and the number of turns of the coil 14 are such that the linear resistance is about several tens of ohms, and the number of ampere turns (AT) is more than 3 and more preferably more than 5 for proper magnetic recording and reproduction. It is decided in consideration of.

The recording circuit 15c is provided with a brake circuit including transistors 72 and 73.
The base terminals of the transistors 72 and 73 are connected to the MHB port of the microcomputer 2, and when one pulse of a high level signal is applied to the MHB port at the end of the magnetic recording, both the transistors 72 and 73 are turned on.

As a result, both ends of the coil 14 are grounded, and the electric charges accumulated around the magnetic head 12 are simultaneously released from the above-described bridge circuits (50, 51, 52, 53), and an unstable recording current is generated. There is no flow through the coil 14. At this time, the resistors 60 and 61 in the bridge circuit act as protection resistors, and no excessive current flows in the bridge circuit.

With this configuration, the floating charge around the magnetic head 12 is instantaneously cleared at the end of the magnetic recording, so that the non-magnetized area can be reliably formed following the end recording. Will be resolved. next,
The operation of the recording / reproducing circuit 15 shown in FIG. 4 during reproduction will be described with reference to waveform diagrams.

FIG. 5 shows the state immediately after passing through the amplifier circuit (before smoothing).
Are shown. One scale on the horizontal axis is about 5
0 ms. The left and right large amplitude parts represent the magnetic data recorded on the magnetic recording layer, and the small amplitude part near the center of the figure represents an area where no magnetic information exists (for example, an area between frames). Represents. Even in a region where no magnetic data exists, the influence of noise of the motor 5 and the like is recognized.

FIG. 6 is an enlarged view of a portion where magnetic data is present, and one graduation on the horizontal axis corresponds to about 1 ms. As shown in the figure, the magnetic data is a combination of a clock pulse having an inverted polarity and a data pulse having a different duty ratio. FIG. 7 shows a waveform diagram when the signal shown in FIGS. 6 and 7 (the signal passed through the amplifier circuit 30) is smoothed by the smoothing circuit 32, and only one side (negative side) is extracted. The noise component is removed by passing through the low-pass filter 33 (see FIG. 8). 7 and 8, one graduation on the horizontal axis corresponds to about 0.2 ms.

In this embodiment, the magnetic head 12 having 300 turns of the coil is used, and the size (thinness) and the cost are reduced as described above. For example, a generally used reproducing head of 1500 turns has a height H (see FIG. 2) of about 6.5 mm, while a magnetic head of about 300 to 600 turns has a height H of 2 mm. This is advantageous when the camera is downsized. It should be noted that as the number of turns of the coil increases, the magnetic head becomes larger and more expensive.

FIG. 9 is a waveform diagram of a reproduction signal from a magnetic head 12 having 300 coil turns, and FIG. 10 is a waveform diagram of a reproduction signal from a magnetic head having 1500 coil turns. By recording a pulse having a polarity opposite to that of the clock pulse in the first half or the second half of one cycle of the clock pulse, if the data pulse of “0” or “1” is recorded, the phase of the data pulse can be accurately determined. When a magnetic head of 300 turns is used as a reproducing head, a reproduced waveform is obtained as shown in FIG. 9, but the reproduced waveform is broken and the phase is read (“0”,
Reading "1") becomes difficult. However, when reproducing magnetic information to detect the first unexposed frame from the film cartridge taken out halfway, it is sufficient to determine whether or not the magnetic information is recorded on the magnetic recording layer and whether or not the magnetic information is recorded. The content of the information, that is, the binary code “1”,
A 300-turn magnetic head can be used as a reproducing head without having to read "0" accurately.

Here, when the number of turns of the coil is further reduced, the level of the reproduced signal is further lowered, and the relation of noise ≧ signal level is satisfied, and it becomes impossible to recognize the presence or absence of the reproduced signal. Table 1 shows an example of the relationship between the number of turns of the coil and signal recognition.

[0055]

[Table 1] Therefore, in this embodiment, a 300-turn magnetic head is used. However, even if it is not possible to read “0” or “1”, if a reproduced waveform capable of recording or not recording a magnetic signal can be output. , 300-turn magnetic head. If the number of turns is large, the drive cannot be performed when used as a recording head. In addition, the number of turns for outputting a reproduction waveform capable of recording or not recording a magnetic signal is reduced by reducing the number of turns of the magnetic head so that the magnetic head can be used as a recording head, reducing the size and cost, and recording the magnetic signal. About 600 is desirable.

Next, the operation of the camera configured as described above will be described with reference to the flowchart shown in FIG. When the film cartridge 8 is loaded in the camera,
First, a DEP-DD process is performed (step S11,
Hereinafter, only the step numbers are shown). In this process, the barcode of the data disk provided in the loaded cartridge 8 is read by the optical reading unit to obtain information such as film sensitivity, film type, and the number of images that can be taken (DD control). By detecting the position of the tongue piece for display, the use state of the loaded cartridge 8 is detected (DEP reading), and these information are stored in a predetermined area of the memory 18.

In step S11, a battery check process shown in the flowchart of FIG. 12 is performed. That is, as shown in FIG. 12, a load current is passed for battery check (BC) (S111), and after a wait time for stabilizing the battery voltage has elapsed (S112), the voltage level of the battery is changed to the A / D port. (S113). Then, the A / D value of the A / D converted battery, a first threshold value,
The second threshold value is compared (S114). Here, the first threshold is a level at which photographing is prohibited, and the second threshold is a first threshold.
The photographing can be performed at a level higher than the threshold value, but this is a level that warns that the battery is exhausted. The voltage level of the battery for performing proper photographing is required to be able to smoothly feed the film for at least one frame in order to perform magnetic recording at the time of one frame advance after photographing.

If the A / D value of the battery is higher than the second threshold, the battery check is approved (BCO)
K) (S115), and after the load current is released (S115).
119), the BC control ends. On the other hand, if the A / D value of the battery is lower than the second threshold but higher than the first threshold, a BC warning display and a BC warning flag are set (S1).
16, S117), and when the A / D value of the battery is lower than the first threshold, BCNG display for prohibiting photographing and B
The CNG flag is set (S116, S118).
When the BCNG flag is set, the operation of the camera thereafter is prohibited. The battery check process is performed for each process described later, and is also performed when a shutter release button is operated or immediately before film rewinding.

Next, in FIG. 11, in S12, S1
As a result of the detection of the use status detected in step 1, the unexposed frame remains, and the film cartridge (partia
Determine if l) has been reloaded. Then, in the case of a film cartridge taken out halfway, a process called mid-roll change (MRC) control is performed (S1).
3). The MRC control subroutine will be described later (FIG. 13).

If it is determined in step S12 that a cartridge other than the film cartridge that has been unloaded is loaded, the process proceeds to step S14, where the cartridge is unused (for example, a new one).
It is determined whether or not the cartridge is a film cartridge. If it is not an unused film cartridge, it is determined that the film cartridge cannot be photographed (exposed), and the processing proceeds to (A) in the figure without performing processing such as film feeding. That is, in the VEI control, by moving the spool 4 and the above-mentioned tongue piece to a predetermined position, a white mark (expose) indicating that the exposure has been completed is set, and the cartridge loading process ends.

On the other hand, if it is confirmed in S14 that the loaded cartridge is unused, the total number of frames Nma is determined based on the information read by the DD control.
The frame set flag indicating x is stored in a predetermined area of the memory 18, and the film is fed in accordance with the value Nmax of the frame set flag. That is, a first frame set (FFS) for feeding the film up to the first photographing frame is executed (S15).

First frame set control (S1
5) Or after the MRC control (S13), the flash charging control is performed (S16), and the initial value setting of the camera is performed (S17). In this way, after the shooting-ready condition has been set,
The state of the manual rewind (MR) switch is confirmed (S18). The MR switch is provided for forcibly rewinding while an unexposed frame remains in the cartridge, and is normally in an off state unless the user turns on the MR switch. M
If the R switch is off, then the state of the release switch is determined. That is, it is determined whether or not the shutter release switch has been pressed. If the release switch is off, the process returns to S18; if the release switch is on, the automatic exposure / autofocus (AE / A)
F) Following the control (S20), the shutter control (S2
1) is executed, and shooting is performed. Then, the magnetic write data such as the photographing conditions relating to the photographed frame is set in the RAM (S22), and then the magnetic information write control is performed at the time of automatic winding of one frame (S23).

More specifically, the MHC port and the MHD port are contradictory, and are respectively H / L controlled and L / H controlled.
An “N magnetization region” or an “S magnetization region” is formed in the magnetic recording region 11 of each frame. At this time, the MRCON port is turned off (H output) and the reference voltage is not supplied to the amplifier circuit 30, but the VOF port of the regulator 22 is turned on (5V).
Output). Therefore, the amplifier circuit 30 functions as a comparator, and the operational amplifiers 36, 37, and 38 are protected.

Next, it is confirmed whether or not the shooting of all frames has been completed (S24). If the shooting has not been completed, that is, if unexposed frames remain, the processing is shown by (B) in the figure. It returns to S18. On the other hand, when the photographing (exposure) of all the frames has been completed, the rewind control for automatically rewinding the film is executed (S25). At this time, by moving the spool 4 and the above-mentioned tongue piece to predetermined positions in the VEI control, the image is set to a white cross (expose) indicating that exposure has been completed.

When the MR switch is turned on in S18, forcible rewind processing (rewind control) is executed (S28). That is, the motor 5 is driven in reverse, the film that has been pulled out is rewound into the cartridge, and the light shielding cover is closed. At this time, the presence or absence of shooting experience is confirmed (S29), and if the film has no shooting experience (unused), the film is set to a white circle (unexpose) indicating that the film is unused in VEI control. And then (S
30) After the process is completed, if the film has experience of photographing, the half-moon mark indicating that unexposed frames remain in VEI control is set to white (patial) (S3).
1) End the process. Thus, when the film cartridge is taken out of the camera, the usage status of the film can be easily confirmed.

Next, the processing of the MRC control will be described. In S12 described above, when it is detected that the cartridge (partial) in which the unexposed frame remains is loaded, the flow shifts to a mid-roll change (MRC) control subroutine shown in FIG. When the MRC control is started, first, an option determination A for determining whether the MRC control may be executed is performed (S40A). In this option determination A, first, the temperature inside the camera is detected. FIG. 14 is a circuit diagram showing an example of the temperature detection circuit. As shown in the figure, the temperature detection circuit includes a transistor Tr that is turned on at the time of temperature detection, a temperature-dependent diode D, and the like. A signal TEMPON (L level signal) that controls ON / OFF of the transistor Tr is output. When added, it outputs a signal TEMPAD corresponding to the camera internal temperature. Then, the A / D value of this signal TEMPAD (TEM
PAD value) is applied to a camera CPU (not shown). The camera CPU determines whether or not the temperature is suitable for the MRC control according to the flowchart shown in FIG.

That is, when detecting the temperature as shown in FIG. 15, the camera CPU sets the L-level signal TEMPON
Is added to the base of the transistor Tr.
Is turned on (S201). Thereafter, after a lapse of a wait time (10 msec) for stabilizing temperature detection (S202), a TEMPAD value corresponding to the camera internal temperature is read from the A / D port (S203). Then, this TEMPAD value and TEMPA at a predetermined reference temperature are obtained.
D value, a constant C (for example, a value set by an experimental value at −10 °, about 1.4 V), and TEMPA
If D> C, it is determined that the temperature is NG, and TEMPAD ≦
In the case of C, it is determined that the temperature is OK (S204).

If it is determined that the temperature is NG, a half-moon mark indicating that unexposed frames remain in the VEI control via a flow line C in FIG. 13 is set to a partial display (S43), and the process is terminated. finish. This is because when the temperature of the photographic film is lowered, its flexibility is also impaired, the feeding unevenness is likely to occur, and magnetic reproduction during MRC control may not be performed well.

In this option determination A, a determination is made according to the type of the film cartridge. That is, FIG.
As shown in FIG. 6, whether the film cartridge loaded in the camera contains color negative film (CN) or color reversal film (CR) is determined from the information of the film cartridge read by the DD control. Then, in the case of a CR film cartridge (S210), the cartridge is determined to be NG, and the process returns to the flow line C in FIG. This is because the magnetic layer of the CR film is thinner than the magnetic layer of the CN film and is not suitable for MRC control.

When the option determination A is approved in this way, the battery check (BC) control is subsequently executed (S41). The battery check detects, for example, the output voltage of the battery 20 while a load current is flowing,
This is performed by comparing the voltage with a predetermined threshold, and when the output voltage of the battery 20 is less than the threshold, the BCN
J is determined to be G, BCNG display is performed, and a BCNG flag is set.

In this embodiment, the threshold value for determining BCNG in the MRC control is a second threshold value (for example, the battery threshold value) higher than the first threshold value for determining BCNG described with reference to FIG. (Threshold set to warn of exhaustion). This is because when a film cartridge taken out halfway is loaded into the camera, it is necessary to determine the exposure frame and the unexposed frame, feed the photographic film up to the first unexposed frame, etc. A large amount of power is required for preparation, and since the exposed and unexposed frames are determined based on the magnetic information recorded on the magnetic recording layer of the photographic film, the photographic film is smoothly fed at a predetermined speed. It is necessary to do it.

In step S42, the state of the BCNG flag is determined. If the BCNG flag is set, power required for processing such as film feeding cannot be obtained. Is set to a white-square display (partial) with a half-month mark indicating that the remaining remains (S43), and the process ends. In this embodiment, the threshold value for determining BCNG in the MRC control is different from the threshold value for determining BCNG described with reference to FIG. 12, but the present invention is not limited to this. , S42, it may be determined whether or not the BC warning flag is set. That is,
When performing the MRC control, the camera operation may be prohibited immediately after the BC warning flag is set.

In step S42, if the BCNG flag is not set, that is, if the remaining amount of the battery is equal to or more than the predetermined amount, the motor 5 is driven to rotate forward, and the film is forward-forwarded (FWD). (S44).
At this time, the VOF terminal of the regulator 22 shown in FIG.
V output, and a driving voltage of 5 V is supplied to the amplifier circuit 30.

The MHC of the microcomputer 2
After confirming that both the port and the MHD port are low (L) output (S45), the MRCON port is set to L output (S46). As described above, by turning on the MRCON, the operational amplifiers 36, 37,
The reference voltage is supplied to 38, and the amplifier circuit 30 operates as an amplifier circuit for amplifying the signal generated by the magnetic head 12.

Then, the photographic film 7 is moved to the magnetic head 12.
Before contacting the film reader, or during the feeding period of the film reader where no magnetic information is apparently recorded.
The A / D value applied to the CIN port is read as reference data (S47). This reference data is read 256 times in synchronization with the encoder pulse,
A reference value (MRCREF) is obtained based on the average or the sum of these data.

As described with reference to FIG. 1, before and after each frame of the photographic film 7, perforations 7a and 7
b is formed, and for the first frame of the film, one more perforation is provided on the leading end side of the film than the perforation 7a on the leading side. Therefore, two perforations are always formed at the head of each photographed frame. Of the two perforations, the first perforation is referred to as the first perforation, and the second perforation is referred to as the second perforation. In S48, the edge of the second perforation is determined based on the output of the photosensor 9 in S48. It is confirmed whether the vehicle has passed (S48). Immediately after the passage of the second perforation is confirmed, the counting of the encoder pulses of the encoder 16 is started (S49).

At this time, an option determination B is performed to determine whether the MRC control can be continued (S40B). In this option determination B, as shown in FIG. 17, the cycle T of the encoder pulse at the time of the film feeding is measured, and when this cycle T is larger than a predetermined reference cycle D (constant) (T> D). It is determined that the film feeding speed has decreased, and the feeding speed is determined as NG (S220).
Returning to the flow line C in FIG. This is because if the feeding speed of the photographic film is lower than a predetermined reference speed, the S / N ratio becomes worse.

Similarly, in option determination B, as shown in FIG. 18, an A / D value (MDCAD) indicating the voltage level of the battery from the A / D port for battery check (BC)
Is read (S230). And this MDCAD is
It is determined whether it is smaller than a preset reference value (A / D value at the time of BC) (S231). When MDCAD <reference value, the film feeding load becomes larger than the load at the time of BC (normally, BC is performed with the maximum load applied). In this case, the film feeding is NG. Returning to the flow line C in FIG. In the embodiment shown in FIG. 18, the magnitude of the film feeding load is determined from the voltage of the battery. However, the present invention is not limited to this, and the motor current is detected, and the detected current value is set in advance. If it is larger than a reference value (for example, a motor current value detected during normal feeding), it may be determined that the film feeding load is large. The motor current can be obtained by measuring a voltage drop when a measurement current is passed through a resistor with a potentiometer.

In this way, option determination B (S40
If B) is approved, the count value (ENCOUNT) counted in S49 is compared with a predetermined constant A (for example, 256) (S50). Then, the count value (ENCO
If (UNT) is smaller than the constant A (for example, 256), the process returns to S49, and when the count value reaches 256, the A / D value of the MRCIN port is read (S50). The reading of the A / D value is performed 256 times in synchronization with the encoder pulse, and the reproduced data (MRCAD) is read based on the average or integration of these data.
Is required (S51).

A MRCADC is obtained by adding a predetermined constant B to the reproduction data (MRCAD) (S52), and a magnitude relationship is determined from a difference or ratio between the reproduction data MRCADC including the margin (constant B) and the reference MRCREF. (S53). If the value of the playback data is small,
This means that magnetic information is recorded on the frame, that is, the frame has been exposed, and the frame count is incremented by one frame (S54), and the process returns to S48.

On the other hand, if the value of the reproduction data is larger in S53, it means that no magnetic information is recorded in the photographed frame, that is, it is an unexposed frame. Is stopped (S55). And
The rewind control is executed (S56), and the film is rewound until it is confirmed that the first perforation of the frame count has passed (S57).

When the passage of the first perforation is detected in S57, the motor 5 is driven forward again to feed the film forward (S58). And
When the second perforation of the frame count is detected, the driving of the motor 5 is stopped (S59). Thereafter, the process returns to the main routine shown in FIG. 11, and the processes after the flash charging control (S16) are performed.

As described above, the camera can take the photographed film 7 once taken into the cartridge 8 and take it out after photographing up to the frame in the middle of the one-roll photograph film 7. ing. When a film cartridge is taken out halfway, the presence or absence of magnetic information recorded on the magnetic recording layer is detected for each frame, thereby detecting the position of the unexposed frame of the film cartridge and photographing the frame. Re-shooting from the frame can be performed.

In this embodiment, if any one of the four determination results in the option determinations A and B (the determinations shown in FIGS. 14 to 18) is NG, the MRC control is performed. However, the present invention is not limited to this. If two or more determination results are NG, M
The RC control may not be performed. In this embodiment, the signal voltage generated at both ends of the coil of the magnetic head is amplified, then smoothed by a smoothing circuit, and the signal level after the smoothing is read to determine the presence or absence of magnetic recording. Alternatively, the presence or absence of magnetic recording may be determined by another circuit that does not use a smoothing circuit.

FIG. 19 is a block diagram showing another embodiment of a circuit for determining the presence / absence of magnetic recording. In the figure, a voltage signal obtained by a magnetic head 12 is amplified via an amplifier circuit 80 and then applied to one input of a comparator 82. The signal from the amplifier circuit 80 is the same as the signal before being input to the smoothing circuit 32 in FIG.

The other input of the comparator 82 is VR
A VR value serving as a comparison reference is added from the value switching circuit 84. The VR value is appropriately switched by the camera CPU 86 so that the left and right large amplitude portions shown in FIG. 5 can be distinguished from the slightly smaller amplitude portions near the center in FIG. That is, the VR value switching circuit 84
Has two ports 1 and 2 as shown in FIG. 20. The four ports shown in the following table depend on whether these ports 1 and 2 are set to ground level (L) or open (OPEN). The VR value can be output.

[0087]

[Table 2] Therefore, when the large amplitude portion shown in FIG. 5 is added to one input of the comparator 82,
The camera C outputs a pulse signal synchronized with either one of the clock pulse and data pulse periods constituting magnetic information.
Output to PU86. When a pulse signal is input from the comparator 82 (that is, when there is a change in the input signal), the camera CPU 86 determines that the frame is an exposure frame, and when no pulse signal is input or when the number of pulses is extremely small (in this case, it is regarded as noise). ), It is determined that the frame is an unexposed frame in which no magnetic information is recorded. In addition, this camera CP
U86 switches the VR value output from the VR value switching circuit 84 to an optimum value so that the output signal from the comparator 82 does not change when magnetic information is not reproduced (when only noise is detected).

[0088]

As described above, according to the camera of the present invention, when a film cartridge that is taken out halfway is loaded, a battery check that is stricter than a normal battery check is performed, so that the film cartridge that is taken out halfway. In addition to guaranteeing that the camera can be properly prepared for shooting, if this guarantee cannot be made, shooting using the film cartridge that has been taken out halfway is prohibited, so that problems such as double exposure can be prevented beforehand. it can.

Further, according to the present invention, when the temperature in the camera is equal to or lower than a predetermined reference temperature which affects the feeding speed of the photographic film when the film cartridge is taken out halfway, the film cartridge has a thin magnetic layer. In the case of a reversal film, at least one of a case where the feeding speed of the photographic film is equal to or less than a predetermined speed and a case where the motor current for feeding the photographic film is larger than the current at the time of normal feeding. If one of the conditions is satisfied, the photographing using the halfway-extracted film cartridge is prohibited. Therefore, it is possible to prevent a problem caused by a case where it is not possible to properly prepare for the halfway-extracted film cartridge.

[Brief description of the drawings]

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

FIG. 2 is a schematic diagram of a magnetic head.

FIG. 3 is an explanatory diagram of a magnetic recording pattern.

FIG. 4 is a circuit diagram showing one embodiment of a recording / reproducing circuit.

5 is a waveform diagram of a signal immediately after passing through the amplifier circuit of FIG. 4 (before smoothing).

6 is a partially enlarged view of the signal shown in FIG.

FIG. 7 is a waveform diagram of a signal immediately after passing through a smoothing circuit.

FIG. 8 is a waveform diagram of a signal after passing through a low-pass filter.

FIG. 9 is a waveform diagram of a reproduction signal from a magnetic head having 300 coil turns.

FIG. 10 is a waveform diagram of a reproduced signal from a magnetic head having 1500 coil turns.

FIG. 11 is a flowchart showing the flow of processing of the camera.

FIG. 12 is a flowchart illustrating a battery check of the camera.

FIG. 13 is a flowchart showing a subroutine of mid-roll change (MRC) control.

FIG. 14 is a circuit diagram illustrating an example of a temperature detection circuit.

FIG. 15 is a flowchart for determining whether or not the temperature is suitable for MRC control.

FIG. 16 is a flowchart for determining whether or not the film cartridge is suitable for MRC control.

FIG. 17 is a flowchart for determining whether or not the film feeding speed is suitable for MRC control.

FIG. 18 is a flowchart for determining whether or not a motor current is suitable for MRC control.

FIG. 19 is a block diagram showing another embodiment of a circuit for determining the presence or absence of magnetic information.

20 is a circuit diagram showing an example of a VR value switching circuit in FIG.

FIG. 21 is an explanatory diagram of a structure of a new standard film cartridge.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 2 ... Microcomputer 4 ... Spool 5 ... Motor 6 ... Drive transmission mechanism 7, 103 ... Photo film 8 ... Film cartridge 9 ... Photo sensor 11, 124, 125 ... Magnetic recording area 12 ... Magnetic head 13 ... Core 14 ... Coil 15 ... Recording / reproduction circuit 15a Power supply circuit 15b Reproduction circuit 16 Encoder 30, 80 Amplification circuit 32 Smoothing circuit 33 Low-pass filter 82 Comparator 84 VR value switching circuit

Claims (8)

[Claims] And determining whether or not the film cartridge loaded in the camera is a film cartridge which has been taken out while a photographic film having exposed frames and unexposed frames is stored in the film cartridge. When the cartridge is determined to be a film cartridge that has been taken out halfway, in the camera that feeds the photographic film from the film cartridge to the first unexposed frame, the voltage of the battery in the camera is equal to or more than a first threshold value for performing appropriate photographing. A first discriminating means for discriminating whether or not the film cartridge loaded in the camera is not the film cartridge taken out halfway, and the first discriminating means determines that the voltage of the battery in the camera is not First prohibiting means for prohibiting photographing when it is determined to be equal to or less than the first threshold value First battery checking means, a second determining means for determining whether or not the voltage of the battery in the camera is equal to or higher than a second threshold value higher than the first threshold value, and a film loaded in the camera. The cartridge is determined to be the film cartridge taken out halfway, and the voltage of the battery in the camera is reduced to the second voltage by the second determination means.
And a second prohibition means for prohibiting the photographing when it is determined to be less than or equal to the threshold value. 2. The camera according to claim 1, wherein the first threshold is a voltage level at which a photographing operation by the camera and a one-frame feed after photographing can be properly performed. 3. The camera according to claim 1, wherein the second threshold value is a voltage level at which a film can be fed to properly detect an unexposed frame of a photographic film from a film cartridge loaded in the camera. camera. And determining whether or not the film cartridge loaded in the camera is a film cartridge which has been taken out halfway and in which a photographic film having exposed frames and unexposed frames is stored in the film cartridge. When the cartridge is determined to be a film cartridge that has been taken out halfway, in a camera that feeds the photographic film from the film cartridge to the first unexposed frame, temperature detection means for detecting the temperature inside the camera, and detection by the temperature detection means Determining means for determining whether or not the temperature inside the camera is equal to or lower than a predetermined reference temperature that affects the feeding speed of the photographic film; and determining that the temperature inside the camera is equal to or lower than the predetermined reference temperature by the determining means. And the film cartridge loaded in the camera is Prohibiting means for prohibiting photographing using the film cartridge taken out halfway when it is determined that the film cartridge has been taken out. 5. A determination is made as to whether or not the film cartridge loaded in the camera is a film cartridge that has been taken out halfway and contains a photographic film having exposed frames and unexposed frames in the film cartridge. A cartridge that detects the type of the film cartridge loaded in the camera in a camera that feeds the photographic film from the film cartridge to the first unexposed frame when the cartridge is determined to be a film cartridge that has been taken out halfway; Determination means for determining whether or not the film cartridge detected by the cartridge type detection means contains a reversal film; and the film cartridge loaded into the camera by the determination means stores the reversal film. Prohibiting means for prohibiting photographing using the film cartridge taken out halfway when it is determined that the film cartridge loaded in the camera is the film cartridge taken out halfway. A camera characterized in that: And determining whether the film cartridge loaded in the camera is a film cartridge which has been taken out halfway and which contains a photographic film having an exposed frame and an unexposed frame in the film cartridge. A camera for feeding the photographic film from the film cartridge to the first unexposed frame when the cartridge is determined to be a film cartridge that has been taken out halfway; speed detecting means for detecting a feeding speed of the photographic film; and Determining means for detecting whether or not the feeding speed is equal to or less than a predetermined speed detected by the means; determining that the feeding speed is equal to or less than the predetermined speed by the determining means; When the loaded film cartridge is removed from the film cartridge And a prohibiting means for prohibiting photographing using the film cartridge taken out halfway when it is determined that the camera cartridge has been removed. 7. A determination is made as to whether the film cartridge loaded in the camera is a film cartridge that has been taken out while a photographic film having exposed frames and unexposed frames is stored in the film cartridge. When the cartridge is determined to be a film cartridge that has been taken out halfway, in a camera that feeds the photo film from the film cartridge to the first unexposed frame, the voltage of the battery in the camera at the time of feeding the photo film becomes a predetermined reference voltage. Determining whether the motor current for feeding the photographic film is greater than a predetermined reference current, and determining whether the motor current for feeding the photographic film is greater than a predetermined reference current. It is determined that the voltage is lower than the predetermined reference voltage or the motor current is determined by the determination unit. Prohibiting means for prohibiting photographing using the film cartridge taken out halfway when it is determined that the film cartridge is larger than a predetermined reference current and the film cartridge loaded in the camera is judged to be the film cartridge taken out partway. A camera comprising: 8. A determination is made as to whether the film cartridge loaded in the camera is a film cartridge that has been taken out halfway and contains a photographic film having exposed frames and unexposed frames in the film cartridge. If the cartridge is determined to be a film cartridge that has been taken out halfway, a camera for feeding the photographic film from the film cartridge to the first unexposed frame detects the temperature inside the camera, and the detected temperature indicates the supply of the photographic film. First determining means for performing a first determination indicating that the temperature is equal to or lower than a predetermined reference temperature affecting a feeding speed, detecting a type of a film cartridge loaded in the camera, and detecting the detected film cartridge as a reversal film; To make a second determination indicating that the Constant means, the photo detecting a feeding speed of the film, a third determination means for performing a third judgment indicating that feeding speed of the detection is a predetermined speed or less which is set in advance,
And either the voltage of the battery in the camera when feeding the photo film is lower than a predetermined reference voltage or the motor current for feeding the photo film is higher than a predetermined reference current. At least two or more of the fourth determination means for performing a fourth determination, and the determination means performs at least two or more of the first to fourth determinations, and A camera comprising: a prohibition unit for prohibiting photographing using the film cartridge taken out halfway when the film cartridge loaded in the camera is determined to be the film cartridge taken out halfway.