JPH06110136A - Information reader and information recorder - Google Patents

Abstract

PURPOSE:To eliminate the inconvenience based on an error in read caused by the fluctuation of carrying speed by giving a warning in the case the mean value and the fluctuation width of the carrying speed is out of relation stored in a storage means. CONSTITUTION:A linear encoder 92 comes into contact with negative film 30, detects the rotational amount of a roller rotating as the film 30 is carried, and outputs a pulse signal in accordance with the rotational amount. An arithmetic circuit 94 counts the number of pulses per unit time inputted from the linear encoder 92, counts an interval between the respective pulses, and calculates the mean value of the carrying speed of the film 30 for every specified time. Then, it calculates the fluctuation width of the carrying speed and outputs the calculated result to a control circuit 78. The control circuit 78 is provided with a non-volatile memory and the relation between the mean value and the fluctuation width of the carrying speed for correctly reading information is recorded in the memory. An alarm 98 for informing an operator of the occurrence of abnormality is connected to the control circuit 78.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information reading device for reading information recorded on a recording medium and an information recording device for recording information on the recording medium.

[0002]

2. Description of the Related Art In recent years, there has been proposed a system in which information such as print size and photographing conditions is recorded on a photographic film in addition to an image, and the information is read and used effectively when printing is performed. In this system, for example, when recording an image on a photographic film provided with a magnetic recording layer, the information is magnetically recorded by a magnetic head and read at the time of printing, or a bar code or the like representing the information outside the screen is optically recorded at the time of recording. Information is transmitted by physically recording and reading at the time of printing. This makes it possible to automatically print each image frame recorded on photographic film in the size desired by the user, to print for each image frame under the optimal printing conditions according to the shooting conditions, to simplify the charge calculation, It is possible to rationalize and improve the efficiency of work in the photo lab. Further, by recording the ID for identifying the user, the ID of the photo lab, and the like, it is possible to prevent mistakes during collation work and collection / delivery.

By the way, photographic film is often fed frame by frame and processed in image frame units, and in order to position the image frame at a predetermined position, a pulse motor is often applied as a motor for transporting the photographic film. . As is well known, since the pulse motor rotates stepwise for each pulse of the input pulse signal, the transport speed when transporting one frame of photographic film and stopping the transport is shown in FIG. It varies as shown. That is, when the tension applied to the photographic film is unstable, the transport speed V greatly changes with respect to the target transport speed when the transport is started and stopped, and the amplitude of the fluctuation gradually decreases with the passage of time. The fluctuation of the transport speed V continues even if a predetermined time or more has elapsed from the start of transport.

When such a change in the transport speed of the photographic film occurs at the time of recording information or reading information, the content of information may change. When, for example, a printing process is performed using the information with the changed contents, there is a possibility that printing may be performed with an incorrect size, or appropriate printing conditions may not be obtained. The inconvenience caused by the fluctuation of the transport speed will be described below by taking as an example the case where information consisting of binary data is magnetically recorded on a photographic film and read.

When recording information, for example, the bit of the value "0" in the information consisting of the binary data is shown in FIG.
Corresponding to the waveform 200 shown in (A), the bit having the value “1” is made to correspond to the waveform 202, and the waveforms 200 and 202 are combined to create the signal 204 representing the information. The waveform 200 rises at the beginning of the cycle T and is 1 /
3 is a waveform that falls when a time T ₁ corresponding to 3 has elapsed, and rises when a time T ₂ that corresponds to ⅔ of the cycle T has elapsed from this falling.
Is a waveform that rises at the beginning of the waveform, falls when the time T ₂ has elapsed, and rises when the time T ₁ has elapsed from the fall.

When the signal 204 is supplied to the recording head while the photographic film is being conveyed, the recording head is moved as shown in FIG.
As shown in FIG. 1 (B), a recording signal 206 having a waveform obtained by differentiating the signal 204 (a waveform in which a pulse is generated at a rising edge and a falling edge) is magnetically recorded, whereby a photographic film is shown in FIG. 11 (C). As described above, the recording signal 206 is magnetized so that the magnetization direction is inverted in the portion where the pulse of the recording signal 206 is generated. When the photographic film magnetized in this way is conveyed and read by the reading head, as shown in FIG.
A read signal 208 is obtained in which a pulse occurs in the portion where the magnetization direction is reversed. Here, when the recording medium is conveyed at a constant speed during information recording and information reading, the ratio of magnetization widths L1: L2
And the pulse interval ratio t ₁ : t ₂ of the read signal 208 is the pulse interval ratio T ₁ : T ₂ (= 1: 1) of the recording signal 206.
2) and the content of information can be accurately judged based on the pulse interval of the read signal 208.

However, as shown in FIG. 12, when the transport speed at the time of recording information changes as shown in FIG. 12B with respect to the recording signal 206 shown in FIG. Along the length varies (Fig. 12 (C))
reference). That is, pulse 210A and pulse 210B
The lengthwise dimension of the magnetized portion 212A caused by the photographic film transport speed V is determined by the pulse 210A and the pulse 210B.
12B corresponds to the result of integration in the section corresponding to the recording timing interval, that is, the area L1 ′ shown in FIG. Similarly, the linear dimension of the magnetized portion 212B caused by the pulses 210B, 210C is such that
This corresponds to the result (area L2 ′) of integration in the section corresponding to the recording timing intervals of 10B and 210C. The same applies to the other magnetized portions.

Therefore, even if the above-described magnetized photographic film is conveyed at a constant speed and information is read by the read head, the pulse interval of the read signal 208 is t ₁ ': as shown in FIG. _{t 2 '= L1': L2} '≠ T 1: T 2 t 1 ": t 2" = L1 ": L2" ≠ T 1: T 2 , and the read error is judged by mistake the value of each bit is generated There is fear.

Further, even if the photographic film is conveyed at a constant speed and magnetized at a ratio of the magnetization widths L1: L2 of exactly 1: 2 as shown in FIG.
If the transport speed changes as shown in FIG. 13, the pulse interval of the read signal 208 changes as shown in FIG. That is, when the conveying speed is low, for example, when the magnetized portion 212A is being conveyed, it takes time to convey the photographic film by the distance L1, and the interval between the corresponding pulses 214A and 214B of the read signal 208 becomes long. Further, when the transport speed is high, for example, when transporting the magnetized portion 212B, the transport of the distance L2 of the photographic film is completed in a short time, and the interval between the corresponding pulses 214B and 214C of the read signal becomes short. Therefore, a reading error may occur.

The above problem similarly occurs when information is optically recorded on a photographic film by a bar code or the like. Therefore, conventionally, a photographic film is conveyed by using a high-precision motor with extremely small speed fluctuation, or the inertial mass of the rotating shaft is increased by attaching a so-called inertia to the rotating shaft of the motor to increase the photographic film. The amount of fluctuation in the transport speed of was reduced.

[0011]

However, in recent years, there has been an increasing demand for miniaturization of photo processing devices,
It is not preferable to use a high-precision motor that tends to be large. Further, when recording information on a photographic film with a camera, it is difficult to mount the large-sized high-precision motor in consideration of portability of the camera. Furthermore, in frame-by-frame transport of photographic film, the transport speed rises and falls instantly at the start and stop of transport, and the accuracy of the stop position is required to be high. However, there is a problem that the fall and stop accuracy are adversely affected.

The present invention has been made in consideration of the above facts, and an object of the present invention is to obtain an information reading apparatus capable of preventing the occurrence of inconvenience due to a reading error due to a change in the conveying speed at the time of reading information.

It is another object of the present invention to provide an information recording apparatus capable of preventing the occurrence of inconvenience due to a reading error due to a change in the transport speed at the time of recording information.

[0014]

The invention according to claim 1 is
Conveying means for conveying the recording medium along a predetermined direction, reading means for reading information recorded on the recording medium at a predetermined recording density, and a recording means for correctly reading information at the predetermined recording density. A storage unit that stores the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed, a detection unit that detects the average value and the fluctuation range of the conveyance speed by the conveyance unit, and the detection unit. Warning means for issuing a warning when the average value of the transport speed and the fluctuation range deviate from the relationship stored in the storage means.

According to a second aspect of the present invention, there is provided a conveying means for conveying the recording medium along a predetermined direction, and a reading means for reading information recorded on the recording medium at a predetermined recording density.
Storage means for storing the relationship between the average value of the transport speed of the recording medium and the fluctuation range of the transport speed for correctly reading information for the predetermined recording density, and the transport speed of the recording medium by the transport means. When detecting means for detecting the average value and the fluctuation range, and when the average value and the fluctuation range of the transport speed detected by the detecting means deviates from the relationship stored in the storage means, when it deviates from the relationship. And a control unit that controls the conveying unit and the reading unit so that the portion corresponding to the reading unit is again corresponded to the reading unit and information is read.

According to a third aspect of the present invention, there is provided a carrying means for carrying the recording medium along a predetermined direction, a recording means for recording information on the recording medium at a predetermined recording density based on a recording signal, and the recording means. Storage means for storing the relationship between the average value of the conveying speed of the recording medium and the fluctuation range of the conveying speed for correctly recording the information represented by the recording signal on the recording medium at the predetermined recording density; Detection means for detecting the average value and fluctuation range of the conveyance speed of the recording medium, and a warning when the average value and fluctuation range of the conveyance speed detected by the detection means deviate from the relationship stored in the storage means. And a warning means for issuing.

According to a fourth aspect of the invention, there is provided a conveying means for conveying the recording medium along a predetermined direction, a recording means for recording information on the recording medium at a predetermined recording density based on a recording signal, and the recording means. Storage means for storing the relationship between the recording density of information for correctly recording the information represented by the recording signal on the recording medium at the predetermined recording density, the average value of the conveyance speed of the recording medium, and the fluctuation range of the conveyance speed. The detecting means for detecting the average value and the fluctuation range of the conveying speed of the recording medium by the conveying means, and the relationship in which the average value and the fluctuation range of the conveying speed detected by the detecting means are stored in the storage means. In the case of deviation, the control means for controlling the conveying means and the recording means such that the part corresponding to the recording means when the relationship is deviated again corresponds to the recording means and the information is recorded. Have There.

[0018]

According to the first aspect of the invention, the storage means has a predetermined memory.
Recording medium for reading information correctly with respect to recording density
Stores the relationship between the average value of the carrier speed and the fluctuation range of the carrier speed
To do. For example, the above figure when transported at a constant transport speed
When a read signal as shown in 11 (D) is obtained,
The pulse interval t of the read signal is changed by the fluctuation of the transport speed. ₁, T
₂If the paper is conveyed so that the size relationship of
Correct the information without causing reading errors due to fluctuations in
Can be read correctly. Therefore, in the above case, the information
Average value of transport speed of recording medium for correct reading
The pulse interval t₁But
Pulse interval t₂And the average value of transport speed that is smaller than
It suffices to find the relationship with the movement width.

By the way, as shown in FIG.
For example, when a photographic film is conveyed by a pulse motor or the like in a photographic processing apparatus or the like, the conveying speed fluctuates in a substantially constant cycle with respect to the target conveying speed, and the fluctuation range is also substantially constant. When the recording medium is conveyed by a pulse motor or the like, it is considered that the conveying speed fluctuates in a constant cycle almost as in FIG. 10. Therefore, the recording medium is conveyed at a target conveying speed, that is, an average value of the conveying speeds. If the fluctuation range of the transport speed that fluctuates in a cycle is obtained, it can be approximated by a sine wave model.

As an example, the inventor of the present invention records information having a predetermined recording density so that a read signal as shown in FIG. 11D can be obtained when the recording medium is conveyed at a constant conveying speed. For the medium, with the recording density as a parameter,
Assuming that the transport speed fluctuates at a constant cycle as described above, the relationship between the average value of the transport speeds at which the pulse intervals t ₁ and t ₂ are equal and the fluctuation width was obtained by simulation (see FIG. 1).

In FIG. 1, the transport speed V is V = AS + SF × sin (2πft + tp) where AS: average speed SF: fluctuation range of speed fluctuation f: frequency of speed fluctuation (variation period T = 1 / f) tp : The phase is approximated and the frequency f is set to 150 Hz by experiment.
Further, since the ratio of the pulse intervals t ₁ and t ₂ changes depending on the phase tp, the phase tp is shifted over one cycle of fluctuation, and if there is a phase where the pulse intervals are equal, the average value of the transport speed at this time, The above-mentioned relationship is obtained by plotting points corresponding to the fluctuation range on the diagram of FIG.

In the above relationship, the range in which the pulse interval t ₁ is smaller than the pulse interval t ₂ (in the OK zone of FIG. 1)
When the recording medium is conveyed so that the average value and the fluctuation range of the conveyance speed are within the range and the information is read, the reading error does not occur due to the fluctuation of the conveyance speed at the time of reading the information. In addition,
It is also possible to experimentally obtain the above relationship by carrying out reading at various carrying speeds and varying widths.

According to the first aspect of the present invention, the average value and the fluctuation range of the conveying speed of the recording medium are detected by the detecting means, and the average value and the fluctuation range of the conveying speed detected by the detecting means are stored in the storage means. In addition, a warning is issued when the relationship is deviated (specifically, when it is deviated from the OK zone). As a result, a warning is issued when a fluctuation in the transport speed that causes a reading error during information reading is detected, and the occurrence of the reading error is notified, so that processing is performed using information that includes the reading error. The occurrence of inconvenience is prevented.

According to the second aspect of the invention, as in the first aspect of the invention, the average value of the transport speed of the recording medium and the variation of the transport speed for correctly reading the information for the predetermined recording density in the storage means. Remember the relationship with width. Then, when the average value and the fluctuation range of the transport speed of the recording medium are detected by the detection means, and the average value and the fluctuation range of the transport speed detected by the detection means deviate from the relationship, Then, the portion corresponding to the reading means is controlled again so that the information is read by the reading means. As a result, when a change in the transport speed that causes a reading error during information reading is detected, the information is read again, and it is possible to obtain information that does not include a reading error, thus preventing inconvenience. To be done.

According to the third aspect of the invention, the average value of the conveying speed of the recording medium and the fluctuation range of the conveying speed for correctly recording the information represented by the recording signal on the recording medium in the storage means at a predetermined recording density. Remember the relationship with. As an example, when the recording medium is conveyed and the recording signal as shown in FIG. 11B is supplied to the recording head to record information, the magnetization width T ₁ shown in FIG. If the paper is conveyed so that the magnitude relationship of T ₂ is not reversed, the information can be correctly read by carrying the paper at a constant speed when reading the information.

The above relationship is obtained by applying a sine wave model or the like and calculating a curve (see FIG. 2) showing the relationship between the average value of the transport speed and the fluctuation width at which the magnetization widths L1 and L2 are equal with the recording density as a parameter. , L1 is L for each recording density
It can be obtained by determining the range of 2 or less (OK zone in FIG. 2). The principle of obtaining the average value of the transport speed and the fluctuation range for correctly recording the information is the same as that for reading the information. For this reason, the above relationship becomes the same as in the case of reading information (FIG. 1), and if the recording medium is conveyed and information is recorded so that the average value of the conveying speed and the fluctuation range are within the OK zone at a predetermined recording density. The reading error does not occur due to the fluctuation of the transport speed at the time of recording information.

According to the third aspect of the present invention, the detection means detects the average value and the fluctuation range of the conveyance speed of the recording medium, and the average value and the fluctuation range of the conveyance speed detected by the detection means are stored in the storage means. In addition, a warning is issued when the relationship is deviated (specifically, when it is deviated from the OK zone). As a result, a warning is issued and a warning is issued when a change in the transport speed at which a reading error occurs during reading is detected during the recording of information, so that the information is recorded so that a reading error occurs. It is possible to prevent the inconvenience from occurring.

According to the fourth aspect of the invention, as in the third aspect of the invention, the average value of the transport speed of the recording medium and the variation of the transport speed for correctly recording the information represented by the recording signal at a predetermined recording density. The relationship with the width is stored in the storage means. And
When the average value and the fluctuation range of the conveyance speed of the recording medium are detected by the detection means, and when the average value and the fluctuation range of the conveyance speed detected by the detection means deviate from the relationship, recording is performed when the relationship deviates from the relationship. The part corresponding to the means is controlled again so that the information is recorded by the recording means. As a result, the information is recorded again when the transport speed fluctuation that causes the reading error during the reading is detected during the information recording, so that the information can be recorded so that the reading error does not occur. It is possible to prevent inconvenience.

In the above description, the case of magnetically recording and reading information has been described as an example, but the same applies to the case of optically recording and reading information. For example, a section in which the recording signal 16 shown in FIG. 3A is supplied to the optical recording unit while the recording medium having photosensitivity is being conveyed at a constant conveying speed, and the recording signal 16 is at a high level. When a light source or the like is caused to emit light for exposure, the recording medium 18 is at a high level at a distance corresponding to the time when the recording signal 16 is at a low level, as shown in FIG. 3B. A bar 18A of width dimension corresponding to time is recorded.

When this recording material is conveyed and is read by, for example, detecting light transmitted through the recording medium, a read signal 20 as shown in FIG. 3C is obtained. If the transport speed changes during information reading, the high level and low level sections of the read signal 20 change. However, by applying the present invention as described above, the relationship as shown in FIG. 1 or FIG. 2 is obtained in advance, and the recording medium is conveyed so that the average value and the fluctuation range of the conveying speed are included in the OK zone. By recording and reading, it is possible to prevent the occurrence of information reading error.

[0031]

Embodiments of the present invention will now be described in detail with reference to the drawings. 4 and 5 show a negative film 30 according to this embodiment. The negative film 30 is provided with an emulsion layer 32 on the upper surface of the transparent base 31 in FIG. 5 so that an image is exposed and recorded. Further, on the lower surface of the transparent base 31 in FIG.
The magnetic recording layer 33 is formed by coating the entire surface of the magnetic recording layer 33.
As shown in FIG. 4, recording tracks S1 along the longitudinal direction of the negative film 30 are formed on the magnetic recording layer 33 at the leading end of the negative film 30 where the image frames 30A are not recorded.
Information is recorded in S2, and in the portion where the image frame 30A is recorded, information is recorded in the recording tracks T1 and T2 corresponding to each image frame.

Information for each one of the negative films 30, for example, information for specifying the user of the negative film 30, is recorded on the recording tracks S1, S2, and information for each image frame 30A, for example, an image, is recorded on the recording tracks T1, T2. Information indicating the shooting conditions of the frame 30A and user information such as a print size for each image frame are recorded. Further, at the tip positions of the recording tracks S1 and S2 and the tip positions of the recording tracks T1 and T2, one perforation 34 is provided for each image frame 30A. Also, the negative film 30
A plurality of perforations 35 for hooking and pulling out the negative film 30 on the claws of a sprocket (not shown) are provided at the tip of the.

FIG. 6 shows a camera 50 to which the present invention can be applied.
And a photographic processing system with a photographic printer 60. On one side of the camera 50, a cartridge 36 for accommodating the negative film 30 wound around a spool 52 is loaded. The camera 50 includes a drive reel 54 driven by the pulse motor 37 (see FIG. 7).
Is provided. The end of the negative film 30 is hooked on the drive reel 54 and conveyed, and an image is taken. The negative film 30 for which a predetermined frame has been photographed is rewound onto the spool 52 of the cartridge 36. The pulse motor 37 is connected to the control circuit 38, and the control circuit 38
Operation is controlled by.

An optical system 40 including a lens 39 and a shutter (not shown) is connected to the control circuit, and the operation of the optical system 40 is controlled to record an image on the negative film 30. Further, in the control circuit 38, information indicating shooting conditions for each image frame 30A, such as the aspect ratio of the image frame 30A recorded on the negative film 30, exposure at the time of shooting, light source information, etc., is output from the optical system after the image frame 30A is shot. Is entered. Further, the camera 50 is provided with an operation unit 41. Information for identifying a user such as a user ID, name, address, etc., title, keyword, shooting location, etc. and user information for each image frame 30A such as title, keyword, shooting location, etc. are input from the operation unit 41 by manual operation. It

A recording head 56 is provided inside the camera 50 corresponding to each track of the negative film 30. The recording head 56 is connected to the control circuit 38 via the recording current amplifier 42 and the modulator 43. The control circuit 38 edits the information input from the optical system 36 and the operation unit 41 for each information to be recorded on each track, and outputs it to the modulator 43 when the negative film 30 is conveyed by the motor 30. The modulator 43 converts the input information into a recording signal as shown in FIG. 11B as an example. This recording signal is amplified by the recording current amplifier 42, and the recording head 56
Is supplied to each track, the tracks are magnetized with a magnetization width corresponding to the recording signal, and the information is magnetically recorded on each track at a predetermined recording density.

The camera 50 has a linear encoder 4
4 are provided. The linear encoder 44 includes a roller that comes into contact with the negative film 30 and rotates as the negative film 30 is conveyed. The linear encoder 44 detects the rotation amount of this roller and outputs a pulse signal according to the rotation amount. The linear encoder 44 is connected to the control circuit 38 via the arithmetic circuit 45.

The arithmetic circuit 45 counts the number of pulses per unit time of the pulse signal input from the linear encoder 44, measures the interval of each pulse, and based on the number of pulses per unit time, negatives at predetermined intervals. Film 30
While calculating the average value of the transport speed of, the maximum value and the minimum value of the pulse interval that changes due to the fluctuation of the transport speed are extracted, and the fluctuation range of the transport speed is determined every predetermined time based on the extracted maximum value and minimum value. Calculate The arithmetic circuit 45 outputs the arithmetic result to the control circuit 38. Further, the control circuit 38 is provided with a non-volatile memory (not shown), and this memory stores the relationship between the average value of the transport speed and the fluctuation range for correctly recording information as shown in FIG. .

On the other hand, the negative film 30 that has been photographed
Is taken out from the camera 50 after being rewound into the cartridge 36, and brought into the lab. In the lab, the negative film 30 is developed, fixed, washed with a developing device (not shown),
After the drying process, the photo printing device 60 is set.

The photographic printing apparatus 60 is provided with a negative carrier 64 arranged on the optical axis of the light source 62. The negative carrier 64 is provided with a solenoid (not shown), and the solenoid is excited in response to an instruction from the control circuit 78 to sandwich and crimp the negative film 30 at the printing position. In the conveyance path of the negative film 30, a pair of conveyance rollers 84, 86,
88 are provided. Conveyor roller pair 84, 86, 88
Rotates by the driving force of the pulse motor 66 and conveys the negative film 30. The pulse motor 66 has a control circuit 78.
And is controlled in operation by the control circuit 78.

A photo sensor 90 for optically detecting the leading edge of the negative film 30 is provided on the upstream side of the conveying roller pair 84.
Is provided. The photo sensor 90 is connected to the control circuit 78. A linear encoder 92 is arranged on the downstream side of the conveying roller pair 84. The linear encoder 92 includes a roller that contacts the negative film 30 and rotates as the negative film 30 is conveyed, like the linear encoder 44 described above. The linear encoder 92 detects the rotation amount of the roller and outputs a pulse signal corresponding to the rotation amount. Is output. The linear encoder 92 is connected to the control circuit 78 via the arithmetic circuit 94.

Similar to the arithmetic circuit 45, the arithmetic circuit 94 counts the number of pulses per unit time input from the linear encoder 92, measures the interval between the pulses, and measures the transport speed of the negative film 30 at predetermined intervals. The average value is calculated and the fluctuation range of the transport speed is calculated, and the calculation result is output to the control circuit 78. The control circuit 78 is provided with a non-volatile memory (not shown), and this memory stores the relationship between the average value of the transport speed and the fluctuation range for correctly reading the information as shown in FIG. Further, the control circuit 78 has an alarm 98 for notifying an operator of occurrence of an abnormality.
Are connected.

On the upstream side of the negative carrier 64 on the conveying path of the negative film 30, the reading head 8 is provided.
0 is set. The reading head 80 is the camera 50.
The information that is magnetically recorded on each track is read by the recording head 56 of, and as an example, as shown in FIG.
It outputs a read signal in which a pulse is generated at a position corresponding to the magnetization width of each track. The output end of the read head 80 is an amplifier 82.
And amplifies and outputs a weak read signal output from the read head 80. The output terminal of the amplifier 82 is connected to the control circuit 78. A photo sensor 96 for detecting the perforations 34 and 35 provided on the negative film 30 is provided between the reading head 80 and the negative carrier 64. The photo sensor 96 is also connected to the control circuit 78.

On the other hand, CMY filters 70 are interposed between the light source 62 and the negative carrier 64, and each filter is controlled by the control circuit 78 so as to appear and disappear on the optical axis according to the exposure amount of each color. To be done. The light rays that have passed through the negative film 30 are irradiated onto the photographic printing paper 74 via the lens 72, and the image of the image frame 30A is printed on the photographic printing paper 74. A shutter 76 is interposed between the photographic printing paper 74 and the lens 72, and is retracted from the optical axis at the time of exposure according to an instruction from the control circuit 78.

Next, the operation of this embodiment will be described with reference to the flow charts of FIGS. 8 and 9. First, shooting and information recording processing by the camera will be described with reference to the flowchart in FIG.

In step 100, it is judged whether or not the cartridge 28 is loaded. Cartridge 2 for camera 50
When 8 is loaded, the determination in step 100 is affirmative, and the process proceeds to step 102. In step 102, so-called prewinding is performed in which the negative film 10 is pulled out from the cartridge 28 and wound around the drive reel 54. In the next step 104, it is determined whether or not an image has been taken. Camera 5
When the shutter switch 0 (not shown) is turned on, the control circuit 32 controls the optical system 36 to expose the image on the negative film 10. As a result, the determination in step 104 is affirmed. Along with this, information representing the shooting conditions and the like of the shot image frame 10A is input from the optical system 36 to the control circuit 32.

When the determination at step 104 is affirmative, at step 106, after the record information including the input information is edited according to a predetermined format,
The pulse motor 37 is driven to start the transportation of the negative film 30. When the recording head 56 corresponds to the tracks T ₁ and T ₂ of the captured image, the recording information is sequentially output to the modulator 42 in step 108. As a result, a recording signal representing the recording information is output from the modulator 42, this recording signal is amplified by the recording current amplifier 40 and supplied to the recording head 56, and recording of information on the tracks T ₁ and T ₂ is started. To be done.

At step 112, the average value and fluctuation range of the transport speed of the negative film 30 output from the arithmetic circuit 45 are fetched. In the next step 114, it is determined whether or not the relationship between the fetched average value of the transport speed and the fluctuation range corresponds to the NG zone of the relationship stored in the memory. If the relationship between the average value of the transport speed and the fluctuation range is within the OK zone shown in FIG. 2, the determination at step 114 is negative, and at step 116 it is determined whether or not the information recording has been completed. If this determination is negative, the process returns to step 112, and the above processing is repeated until the determination of step 116 is positive.

By the way, when the speed fluctuation becomes large during the recording of the information and the relationship between the average value of the transport speed and the fluctuation range is within the NG zone, a read error may occur even if the recorded information is read. There is a nature. In such a case, the determination in step 114 described above is affirmed, and step 1
At 18, the negative film 30 is rewound to the beginning of the tracks T ₁ and T _{2 and} the process returns to step 108. As a result, the recording of the information on the tracks T ₁ and T ₂ is performed again, so that it is possible to prevent the information from being recorded so that a reading error occurs when the information is read.

If the determination in step 114 is affirmative, the photographer may be notified by sounding an alarm instead of rerecording the information as described above. Especially in a camera, since the power source is a battery, the transport speed may always fluctuate greatly due to a decrease in power source voltage or the like. In such a case, the photographer can detect the exhaustion of the battery before the inconvenience that the information is not recorded due to the alarm and can replace the battery at an appropriate timing.

When the recording of the predetermined information on the tracks T ₁ and T ₂ is completed and the determination in step 116 is affirmed, it is determined in step 120 whether or not the recording of the number of the negative film 10 has been completed, for example, 3 with 36 negative film
It is determined whether or not shooting has been performed six times. When the determination in step 120 is negative, the process returns to step 104, and steps 104 to 120 are repeated until the determination in step 120 is affirmative, and the negative film 10 is photographed for the number of photographed images and information about the photographed images. Are recorded on tracks T ₁ and T ₂ .

When the determination in step 120 is affirmative, the recording of user information on the tracks S ₁ and S ₂ is performed in the same manner as above in the subsequent step 122 and subsequent steps. That is, in step 122, it is determined whether or not the user information for identifying the user is input, and when the user information is input by operating the operation unit 41 or the like, in step 124, the record information is edited according to a predetermined format. After that, the conveyance of the negative film 30 is started, and when the tracks S ₁ and S ₂ correspond to the recording head 56, recording of information is started in step 126. At step 128, the average value of the transport speed and the fluctuation range are fetched from the arithmetic circuit 45, and at step 130, the relationship between the average value of the transport speed and the fluctuation range that has been fetched is NG.
It is determined whether or not it corresponds to the zone.

If the relationship between the average value of the transport speed and the fluctuation range is within the OK zone, the determination at step 130 is denied and the information recording is continued. When the determination in step 130 is affirmative, the negative film 30 is rewound to the beginning of the tracks S ₁ and S ₂ in step 134, and the process returns to step 124 to record the information on the tracks S ₁ and S ₂ again. To do. When the determination in step 132 is affirmative, the negative film 30 is housed in the cartridge 36 in step 136, and the process is ended.

Next, with reference to the flow chart of FIG. 9, information reading and printing processing in the photo printing apparatus 60 will be described. The negative film 10 on which an image has been taken by the camera 50 is received at a DPE store, and subjected to processing of development, fixing, washing with water, and drying in a laboratory, and then set in the photo printing apparatus 60 in the case of simultaneous printing. As a result, the flowchart of FIG. 6 is executed.

In step 140, it is determined whether or not the negative film 30 is set by determining whether or not the leading edge of the negative film 30 is detected by the photo sensor 90. If the determination in step 140 is positive, step 1
At 42, the pulse motor 66 is driven to start the conveyance of the negative film 30. In step 144, the photo sensor 96
It is determined whether the perforation of the negative film 30 is detected by. At the tip of the negative film 30, perforations 34 are provided corresponding to the tracks S ₁ and S _2.
Is provided, and in step 144, the photo sensor 9
The perforation 34 is detected by 6.

When the determination in step 144 is affirmative and the photosensor 96 detects the perforation 34, the tracks S ₁ and S ₂ have reached the position where the read head 80 is provided, and in the next step 146, the track S by the read head 80. _1, it starts reading the information from S _2.
In step 148, the arithmetic circuit 94 to the negative film 30
Take in the average value and fluctuation range of the transport speed of. Step 1
At 50, it is determined whether or not the relationship between the average value of the taken transport speed and the fluctuation range corresponds to the NG zone of the relationship stored in the memory. If the relationship between the average value of the transport speed and the fluctuation range is within the OK zone for the recording density of the information recorded on the negative film 30 in FIG. 1, the determination in step 150 is negative and the information is read in step 152. It is determined whether or not it has ended. While the reading is not completed, the process returns to step 148 and the above process is repeated.

By the way, when the speed fluctuation becomes large during the reading of the information and the relationship between the average value of the transport speed and the fluctuation width becomes the NG zone, the read information may include an error. . In this case step 1
The affirmative determination is made at 50, and the negative film 30 is rewound to the beginning of the tracks S ₁ and S ₂ at step 154. Further, in step 156, it is determined whether or not the rewinding process in step 154 has been performed a predetermined number of times on the same track. If the determination in step 156 is negative, the process returns to step 142. As a result, the same tracks S ₁ , S
_Since the information from ₂ is read again, the information without error can be obtained.

If a large speed fluctuation corresponding to the NG zone is detected even after rereading a predetermined number of times,
It is conceivable that some inconvenience has occurred in the transport system. Therefore, if the determination in step 156 is affirmative, the alarm 98 is activated in step 158 to notify the operator, and the process ends. As a result, an abnormality in the transport system is detected, and the inconvenience caused by performing the process using the information including the error is prevented.

If the determination in step 150 is positive, the alarm 98 may be activated without rewinding the negative film 30. If the determination in step 152 is affirmative, the process proceeds to step 160, and the read information is stored. The information recorded on the tracks S ₁ and S ₂ is the information for specifying the user, and the stored information is supplied to the subsequent process and used in the collation process for collating the negative film and the print.

On the other hand, after the next step 170,
Cook T₁, T₂Reads information from the
U That is, in step 170, the pulse motor 66 is turned on.
The negative film 30 is driven to start conveyance, and step 1
In 72, the perforation is performed by the photo sensor 96.
It is determined whether 34 is detected. Format of step 172
Is confirmed and the perforation 34 is detected
On track T₁, T₂Reaches the position where the read head 80 is installed
Has been reached, and in step 174 the read head 80
Start reading information. In step 176, calculation times
The average value of the transport speed of the negative film 30 from the path 94 and the variation
The moving speed is taken in, and the carrying speed taken in is taken in step 178.
Whether the relationship between the average value and the fluctuation range is included in the NG zone
Determine whether. The relationship between the average value of the transport speed and the fluctuation range is OK.
If it is in the zone, the determination in step 178 is negative.
And whether or not the reading of information is completed in step 180
Until the determination in step 180 is positive.
Steps 176 to 180 are repeated. Step 1
If the determination at 78 is affirmative, a negative determination is made at step 182.
Film 30 on track T₁, T ₂Rewind to the beginning of
In step 184, it is determined whether or not the film has been rewound a predetermined number of times. Ste
If the determination in step 184 is negative, step 170
Back to track T₁, T ₂Re-read information from
Do once.

If the determination in step 184 is affirmative, the alarm 98 is activated in step 186 to notify the operator and the process is terminated. As a result, there will be no inconvenience such as setting improper printing conditions based on the information containing the error and performing the printing process, as will be described later.

On the other hand, when the information is correctly read from the tracks T ₁ and T ₂ , it is determined in step 188 whether the image frame 30A corresponding to the tracks T ₁ and T ₂ has reached the printing position, and the step If the determination at 188 is affirmative, at step 190, the conveyance of the negative film 30 is stopped and the image frame 30A is positioned at the printing position. In step 192, the positioned image frame 30A is subjected to photometry by a density sensor (not shown), and based on the photometric value obtained by this photometry and the information indicating the photographing condition and the print size included in the read information, The printing condition of the image frame 30A is set. In the next step 194, the light source 62, the filter 70, and the shutter 7 are set according to the set printing conditions.
6 and the like to control the image of the image frame 30A
Bake to 4.

In step 196, it is determined whether or not the printing process of all the image frames 30A of the negative film 30 has been completed. If the determination in step 196 is denied, the process returns to step 170, and steps 170 to 196 are repeated until the determination in step 196 is affirmed. When the determination in step 196 is affirmative, the negative film 30 is housed in the cartridge 36 in step 198, and the process is ended.

In the present embodiment, when the recording or reading of information is performed again, the tracks T ₁ and T ₂ or the tracks S ₁ and S ₂ are rewound to the beginning, but the present invention is not limited to this. However, at least when the relationship between the average value of the transport speed and the fluctuation width is within the NG zone, the information is recorded or read again on the portion corresponding to the recording head or the reading head. Alternatively, the tracks may be rewound to the middle.

In the present embodiment, the relationship shown in FIG. 1 is stored as the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed for correctly reading the information, and the information is recorded correctly. Although the relationship shown in FIG. 2 is stored as the relationship between the average value of the transportation speed of the recording medium and the fluctuation range of the transportation speed, it is possible to determine whether or not the information can be read and recorded correctly. All that is required is, for example, FIG.
Alternatively, only the relationship between the average value of the transport speed and the fluctuation range corresponding to the OK zone in FIG. 2 may be stored. Similarly, only the relationship between the average value of the transport speed and the fluctuation range corresponding to the NG zone in FIGS. 1 and 2 may be stored. Further, in FIG. 1 and FIG. 2, the relationship between the average value of the transport speed and the fluctuation range corresponding to the curve corresponding to the boundary between the OK zone and the NG zone may be stored.

In this embodiment, the present invention is applied to the case where information is magnetically recorded and read on the negative film 30, but the present invention is not limited to this, and is optically. It is also applicable when recording and reading information. The recording medium is various media such as a magnetic tape coated with a magnetic material when magnetically recording or reading information, and a photosensitive medium when optically recording or reading information. A medium such as a material can be applied.

[0066]

As described above, according to the first aspect of the invention, the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed for correctly reading the information for the predetermined recording density is shown. Since the warning is issued when the average value and the fluctuation range of the detected transportation speed deviate from the stored relationship, it is possible that an inconvenience occurs due to a reading error due to the fluctuation of the transportation speed at the time of reading information. The excellent effect that it can be prevented is obtained.

According to the second aspect of the present invention, the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed for correctly reading the information for a predetermined recording density is stored, and the detected conveyance is detected. When the average value of the speed and the fluctuation range deviate from the stored relationship, the recording medium is conveyed so that the part corresponding to the reading unit when positioned outside the relationship is located upstream of the reading unit. Since the reading is performed again, there is an excellent effect that it is possible to prevent a problem from occurring due to a reading error due to a change in the transport speed at the time of reading the information.

According to the third aspect of the present invention, the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed for correctly recording the information represented by the recording signal on the recording medium at a predetermined recording density is shown. Since the warning is issued when the average value and the fluctuation range of the detected conveyance speed deviate from the stored relationship, it is possible to avoid inconvenience due to a reading error due to the fluctuation of the conveyance speed during information recording. The excellent effect that it can be prevented is obtained.

According to the fourth aspect of the present invention, the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed for correctly recording the information represented by the recording signal on the recording medium at a predetermined recording density is shown. If the average value and the fluctuation range of the stored and detected conveyance speed deviate from the stored relationship, the part corresponding to the recording means when the relationship deviates from the relationship is located upstream of the recording means in the predetermined direction. Since the recording medium is conveyed so as to be positioned and recording is performed again, it is possible to prevent an inconvenience from occurring due to a reading error due to a change in the conveying speed at the time of recording information.

[Brief description of drawings]

FIG. 1 is a diagram showing a result obtained by simulating a relationship between an average value of a conveyance speed and a fluctuation range, assuming that a conveyance speed at the time of reading fluctuates in a constant cycle using a recording density as a parameter.

FIG. 2 is a diagram showing a result obtained by simulating a relationship between an average value of the conveyance speed and a fluctuation width, assuming that the conveyance speed at the time of recording fluctuates in a constant cycle using the recording density as a parameter.

3A is a waveform diagram showing a recording signal in the case of optically recording information, FIG. 3B is a plan view showing a recording medium on which information is optically recorded, and FIG. It is a waveform diagram showing.

FIG. 4 is a plan view of a negative film according to this example.

5 is a cross-sectional view taken along line VV of FIG.

FIG. 6 is a schematic configuration diagram of a photographic processing system including a camera and a photographic printing apparatus.

FIG. 7 is a block diagram showing a schematic configuration of a camera.

FIG. 8 is a flowchart illustrating a shooting and information recording process performed by a camera.

FIG. 9 is a flowchart illustrating information reading and printing processing in the photographic processing apparatus.

FIG. 10 is a diagram showing an example of fluctuations in film transport speed when a photographic film is transported frame by frame.

11A is a waveform diagram showing a signal created according to information, FIG. 11B is a recording signal of the signal shown in FIG. 11A, and FIG. FIG. 3D is a plan view showing the magnetization state of the magnetic recording portion, and FIG. 3D is a waveform diagram showing a read signal when the information is read while being conveyed at a constant speed.

FIG. 12A is a waveform diagram showing a recording signal, FIG. 12B is a diagram showing variations in the transport speed, and FIG. 12C is a diagram showing magnetization in the magnetic recording portion in the state of being varied as shown in FIG. FIG. 4D is a plan view showing the state of FIG. 3D, and FIG. 4D is a waveform diagram showing a read signal when the magnetic recording portion of FIG.

13A is a plan view showing a magnetized state of a magnetic recording portion, FIG. 13B is a diagram showing a change in transport speed, and FIG. 13C is a state in which the magnetic recording part is changed as shown in FIG. It is a wave form diagram which shows the read signal at the time.

[Explanation of symbols]

 30 negative film 33 magnetic recording layer 37 pulse motor 38 control circuit 44 linear encoder 45 arithmetic circuit 50 camera 56 recording head 60 photo printing device 66 pulse motor 78 control circuit 80 read head 92 linear encoder 94 arithmetic circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI Technical display location G06K 7/00 K 8623-5L G11B 5/02 Z 7426-5D 15/02 C 8022-5D

Claims (4)

[Claims] 1. A conveying means for conveying a recording medium along a predetermined direction, a reading means for reading information recorded on the recording medium at a predetermined recording density, and information for the predetermined recording density. Storage means for storing the relationship between the average value of the transport speed of the recording medium and the fluctuation range of the transport speed for correct reading, a detection means for detecting the average value and the fluctuation range of the transport speed by the transport means, and the detection An information reading device which issues a warning when the average value and the fluctuation range of the transport speed detected by the means deviate from the relationship stored in the storage means. 2. A conveying means for conveying a recording medium along a predetermined direction, a reading means for reading information recorded on the recording medium at a predetermined recording density, and information for the predetermined recording density. A storage unit that stores the relationship between the average value of the conveyance speed of the recording medium and the fluctuation range of the conveyance speed for correct reading, and a detection unit that detects the average value and the fluctuation range of the conveyance speed of the recording medium by the conveyance unit. When the average value and the fluctuation range of the transport speed detected by the detecting means deviate from the relationship stored in the storage means, the part corresponding to the reading means when deviating from the relationship is An information reading apparatus comprising: a control unit that controls the conveying unit and the reading unit so that the information is read again corresponding to the reading unit. 3. A conveying means for conveying a recording medium along a predetermined direction, a recording means for recording information on the recording medium at a predetermined recording density based on a recording signal, and information represented by the recording signal. Storage means for storing the relationship between the average value of the transport speed of the recording medium and the fluctuation range of the transport speed for correctly recording on the recording medium at the predetermined recording density, and the transport speed of the recording medium by the transport means. Detection means for detecting the average value and the fluctuation range, and a warning means for issuing a warning when the average value and the fluctuation range of the transport speed detected by the detection means deviates from the relationship stored in the storage means, An information recording device having a. 4. A conveying means for conveying a recording medium along a predetermined direction, a recording means for recording information on the recording medium at a predetermined recording density based on a recording signal, and information represented by the recording signal. Storage means for storing the relationship between the recording density of information for correctly recording on the recording medium at the predetermined recording density, the average value of the conveying speed of the recording medium, and the fluctuation range of the conveying speed; The detection means for detecting the average value and the fluctuation range of the conveyance speed of the recording medium, and when the average value and the fluctuation range of the conveyance speed detected by the detection means deviate from the relation stored in the storage means, An information recording apparatus comprising: a control unit that controls the conveying unit and the recording unit so that a portion corresponding to the recording unit when the relationship is removed is again associated with the recording unit and information is recorded.