JP2006243148A - Synchronous photographing apparatus for film camera and digital camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable a plurality of kinds of film cameras and digital cameras to perform a synchronous photographing. <P>SOLUTION: The synchronous photographing apparatus for the film camera and the digital camera is composed of: a synchronous apparatus main body 1; a remote switch 2; and cables 5 and 9 for connecting, via a connector, the respective remote release function input parts of the film camera 3 and digital camera 4 and the remote release function output part of the synchronous apparatus main body. Remote release function output parts corresponding to the film camera and digital camera are caused to generate corresponding remote shutter release signals after corresponding delay times set by a delay time setting means. In order to attain synergistic effects of the film camera and the digital camera by synchronously photographing a subject with both the cameras, it matters how precisely synchronize them in accordance with the shutter operation characteristics of both the cameras. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a synchronized photographing apparatus for a film camera and a digital camera.

Conventionally, in a photo studio or the like, since a high-quality photographic print can be obtained, a film camera that exposes a subject image on a silver salt film and develops it has been used.

  However, the film camera has the advantage of obtaining high-quality photo prints, but the photographed images cannot be confirmed until the print process is complete, so the customer can choose their favorite photo immediately after taking multiple photos. I couldn't choose. Further, the film camera has a drawback that it is relatively difficult to correct an image after photographing.

  On the other hand, in recent years, there has been a remarkable improvement in the quality of photographic prints coupled with the improvement in quality of printers, but in terms of image quality, film cameras still have a long day. Currently.

  In recent years, various techniques have been proposed in which a subject is photographed simultaneously with a film camera and a digital camera to achieve a synergistic effect of the two and to compensate for the above-described drawbacks.

  Firstly, Patent Document 1 discloses an optical system of an exposure unit that exposes a subject image on a silver salt film, and an image signal output from the solid-state image sensor that forms an image corresponding to the subject image on the solid-state image sensor. The optical system of the image signal recording means for recording is configured separately, and the lens that configures the former optical system and the lens that configures the latter optical system are arranged above and below the camera body. Is provided with a monitor for displaying an image based on the image signal, and further, the distance from the subject image is set so that the image range displayed on the monitor is the same as the subject image exposed on the silver halide film. Accordingly, there has been proposed a camera in which an image signal processing means for processing the image signal is provided and in which a film camera and a digital camera are integrated.

  Further, Patent Document 2 aims to provide a digital camera that obtains a video signal without a time lag in photographing a subject by both a film camera and a digital camera, and the shutter control means is synchronized with the release signal from the release means. The first drive signal is supplied to the shutter of the film camera, the shutter is opened to expose the film of the film camera, and the second drive signal synchronized with the release signal is supplied to the imaging means of the digital camera. Thus, a technique is proposed in which shooting is performed with the electronic shutter of the image pickup means opened. That is, in Patent Document 1, shooting is performed by simultaneously generating shutter drive signals of a film camera and a digital camera by a release signal from a release means.

Japanese Patent Laid-Open No. 9-311378 JP-A-8-223460

However, such conventional techniques have the following problems.
Firstly, in Patent Document 1, since a special camera that integrates a film camera and a digital camera is newly produced, it has been used and improved over many years, among professionals such as photo studios. It is not possible to use an existing model of film camera that is said to be a popular name machine, and even digital cameras have improved dramatically in recent years, so that they can withstand professional use. It is also impossible to use existing existing models.

  On the other hand, in Patent Document 2, since filming is performed by synchronizing a film camera and a digital camera with a synchronization signal generator, an existing film camera or digital camera with good performance should be used as the camera to be used. However, in each camera synchronization method proposed in this document, as shown in FIG. 3 of the document, the shutter drive signals of the film camera and the digital camera are generated by the release signal from the release means. The images are generated at the same time, and the shutter operation time from when the shutter drive signal is input to the actual shooting is not considered in each camera.

  In general, film cameras and digital cameras used by professionals such as photo studios share a shooting lens and a viewfinder lens, and have a structure called a so-called single-lens reflex camera that has a structure in which the mirror jumps before the shutter operates. There are many things. However, even with the same single-lens reflex camera, digital cameras generally do not have a focal plane shutter that a single-lens reflex camera has, so the time from when the shutter release switch is turned on until actual exposure varies greatly depending on the model. For example, digital cameras tend to be about 100 ms faster.

  FIG. 9 shows the exposure timing of the digital camera and the film camera when the shutter release switch is simultaneously turned on. As shown in the figure, when the shutter release switch is turned on, in a digital camera, the shutter is opened for a predetermined time after the mirror raising time has elapsed, and in the film camera, exposure is performed at the mirror raising time. Since the operation time is added and the exposure is performed after that, the exposure time is shifted. For this reason, if the flash is fired in synchronization with the opening operation of the shutter of the film camera, the digital camera is exposed before the flash is fired to capture the subject image.

  On the other hand, some film cameras used by professionals such as photo studios use lens shutters instead of focal plane shutters. In such film cameras, shutter release switches are used compared to other film cameras. The time from turning ON to actual exposure is short.

  In digital cameras, the time from when the shutter release switch is turned on until actual exposure varies greatly depending on the manufacturer and model.

  From the above, in order to shoot a subject with a film camera and a digital camera at the same time and to achieve a synergistic effect between them, it is important how to synchronize the two according to the shutter operating characteristics of both. It has become.

  The present invention has been made in view of the above-described conventional problems, and an object of the present invention is to enable synchronized shooting with a plurality of types of film cameras and digital cameras.

  In order to achieve the above-described object, in the present invention, the synchronization device body, the remote switch, the remote release function input unit of each of the film camera and the digital camera, and the remote release function output unit of the synchronization device body are connected via a connector. The synchronization device main body includes a model discriminating means for discriminating the model by a film camera cable connected to the remote release function output unit, a delay time selecting means capable of selecting a delay time, A delay time setting means for setting the delay time of the remote shutter release signal of the digital camera with respect to the remote shutter release signal of the film camera from the model determined by the model determination means and the delay time selected by the delay time selection means; And remote release compatible with digital cameras A film camera and a digital camera synchronous photographing apparatus having a remote shutter release signal generating means for generating respective remote shutter release signals with a delay time set by the delay time setting means in the active output section. Is.

  According to the present invention, in the above-described configuration, an adjustable delay time is added between the remote shutter release signal generating means of the digital camera and the corresponding remote release function output unit, and the digital camera for the remote shutter release signal of the film camera is added. It has been proposed to provide delay time adjusting means capable of adjusting the delay time of the remote shutter release signal.

  Further, in the present invention, in the above configuration, the delay time adjusting means is constituted by two monostable multivibrators connected in cascade, and the delay time to be added can be adjusted by adjusting the pulse width of the previous monostable multivibrator, It has been proposed to generate a remote shutter release signal by a monostable multivibrator at the latter stage.

  Furthermore, in the present invention, in the above configuration, the film camera cable is provided with model identification information by short-circuiting between the empty pins selected according to the model from the plurality of empty pins of the connector, The model discriminating means proposes a synchronous photographing device for a film camera and a digital camera configured to detect and detect a signal of a model discriminating line connected to a connector pin on the synchronizer body corresponding to a short-circuited empty pin. .

  Further, according to the present invention, in the above configuration, the remote release function has an autofocus function in addition to the remote shutter release function, and the remote switch has a switch unit corresponding to the autofocus function and a remote shutter release function. It is proposed to provide a switch part.

  Furthermore, in the present invention, in the above configuration, it is proposed that the remote switch has a configuration in which the operating range of the remote shutter release function is set inside the operating range of the autofocus function when the common push button is pressed. ing.

  In the present invention described above, the synchronization device main body determines the model by the film camera cable connected to the remote release function output unit, and the delay time of the delay time setting means according to the model of the digital camera connected via the cable. By selecting an index corresponding to, the shutter operation characteristics of the film camera and the digital camera are input to the synchronization device body.

  Thus, the synchronizer body sets the delay time of the remote shutter release signal of the digital camera relative to the remote shutter release signal of the film camera according to the model from the determined model and the delay time selected by the index by the delay time selection means. A remote shutter release signal is generated at the output part of the remote release function corresponding to the film camera and the digital camera, respectively, with a delay time, thereby absorbing the difference in shutter operation characteristics between the film camera and the digital camera. Thus, it is possible to perform shooting in which both are accurately synchronized.

  Since the shutter operation characteristics of digital cameras vary considerably depending on the manufacturer and model, providing a delay time adjusting means in addition to the delay time selecting means described above makes it possible to deal with various types of digital cameras.

  The film camera model is determined by providing model identification information by short-circuiting the unused pins selected according to the model from the plurality of unused pins of the cable connector. If it is configured to detect the signal of the model identification line connected to the connector pin on the synchronizer body side corresponding to the short pin that is short-circuited, the film camera model can be automatically identified reliably. Good usability.

Next, embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is an explanatory diagram showing an example of the overall configuration of a synchronous photographing apparatus according to the present invention. In this embodiment, main components are configured using a peripheral device connection control IC (PIC: Periferal Interface Controller). It is. Of course, in other embodiments, the main components may be configured by a computer device or may be configured by using discrete circuit elements.
A portion surrounded by a two-dot chain line of reference numeral 1 indicates a synchronizer main body, reference numeral 2 indicates a remote switch, 3 (3a, 3b) indicates a film camera, and 4 indicates a digital camera. In the figure, two film cameras 3a and 3b are shown. However, since these are used selectively, one film camera 3b and its corresponding elements are indicated by broken lines for convenience. Reference numeral 5 denotes a cable for connecting the remote release function input unit 6 of the film camera 3 and the remote release function output unit 7 of the synchronizer body 1 via the connectors 8 (8i, 8o). Reference numeral 9 denotes a cable for connecting the remote release function input unit 10 of the digital camera 4 and the remote release function output unit 11 of the synchronizer body 1 via the connector 12 (12i, 12o). Therefore, as described above, the synchronized photographing apparatus of the present invention generally includes the synchronization apparatus body 1, the remote switch 2, the remote release function input units 6 and 10 of the film camera 3 and the digital camera 4, and the synchronization apparatus. The cable 5 and 9 which connect the remote release function output parts 7 and 11 of the main body 1 via the connectors 8 and 12 are used as components. Reference numeral 13 denotes a cable for connecting the remote switch 2 and the switch input unit of the synchronizer body 1 via the connectors 14 (14o, 14i).

  In this embodiment, the remote release function includes a remote shutter release function and an autofocus function. Accordingly, the remote release function input units 6 and 10 in the film camera 3 and the digital camera 4 may be configured by a plurality of input terminals in addition to a single input terminal.

  Next, an embodiment of the synchronizer main body 1 will be described. In this embodiment, main components are configured by using a peripheral device connection control IC (PIC: Periferal Interface Controller).

  That is, reference numeral 15 denotes a control IC, and for example, a type such as PIC16F84A can be used. The terminal MCLA is for a master reset input, and the output of the voltage monitoring circuit 16 is connected to this terminal. The battery voltage, in this case, the Vdd voltage drops from a predetermined voltage, for example, 6V to 4.5V or less. In such a case, the voltage monitoring circuit 16 operates, and a reset signal is given to the terminal MCLA to stop all operations.

  Reference numeral 18 denotes a selection operation switch having five switching contacts 17a to 17e. These switching contacts 17a to 17e are connected to the terminal groups RB0 to RB4 and pulled up by resistors, and the common contact 17f is grounded. Yes. For this reason, in the state shown in the figure, the terminal RB2 corresponding to the common contact 17f and the conductive contact 17c becomes L level, which becomes a selection signal. Therefore, these elements constitute the delay time selection means.

  As described above, the remote release function includes the remote shutter release function and the autofocus function, and the remote release function output unit 7 of the film camera 3 includes the remote shutter release output circuit 19a and the autofocus output circuit 19b. These output units 19a and 19b use photo relays to reduce the ON resistance.

  The remote switch 2 includes a switch contact 20a corresponding to the autofocus function, a switch contact 20b corresponding to the remote shutter release function, and a ground contact 20c. The switch contact 20a is connected to the connector 14 (14o, 14i). The pin 1 is connected to the input portion of the auto-focus output circuit 19b and the pin 1 of the connectors 12i and 12o of the remote release function output portion 11 of the digital camera 4 and is also connected to the terminal RA2 of the PIC 15. It is connected to the output part of the holding circuit 20. As described above, the switch contact 20a corresponding to the autofocus function of the remote switch 2 shifts to the L level by the ground contact 20c in the start operation of the autofocus function, so that the autofocus of the remote release function output unit 6 of the film camera 3 is performed. The output circuit 19 b is operated, and the autofocus function of the digital camera 4 is operated from the 1 pin of the connector 12 via the cable 9. The remote switch 2 can be configured such that, for example, in the push operation of a common push button, the operation range of the remote shutter release function is set inside the operation range of the autofocus function.

  On the other hand, the switch contact 20b corresponding to the remote shutter release function of the remote switch 2 is connected to the terminal RB5 of the PIC 15 via the 3 pin of the connector 14. That is, the terminal RB5 of the PIC 15 is shifted to the L level by the ground contact 20c in the start operation of the remote shutter release function in the remote switch 2, so that the terminal RB5 of the PIC 15 is shifted to the L level and the remote shutter release function is operated. The configuration is to let

  The input part of the remote shutter release output circuit 19a is connected to the terminal RA1 of the PIC 15, and the PIC 15 is configured to operate the remote shutter release output circuit 19a by shifting the terminal RA1 to the L level.

  On the other hand, in the PIC 15, the operation output of the remote shutter release function for the digital camera 4 is configured to be emitted from the terminal RA0, but there is a delay time between the terminal RA0 and the remote release function output unit 11. The adjusting means 21 is configured.

  This delay time adjusting means 21 is composed of two monostable multivibrators 22a and 22b connected in cascade, and the delay time to be added can be adjusted by adjusting the pulse width of the previous monostable multivibrator 22a. The monostable multivibrator 22b generates a remote shutter release signal for a predetermined time. In this configuration, the pulse width of the monostable multivibrator 22a in the previous stage can be adjusted by the variable resistor 23. The pulse output of the subsequent monostable multivibrator 22b is H level, and the switch circuit 24 is operated by this output to obtain L level output. Further, the output of the subsequent monostable multivibrator 22b is inputted to the terminal RA3 of the PIC 15, and the operation of the delay time adjusting means 21 is monitored through this terminal RA3.

  On the other hand, the cable 5 of the film camera 3 (3a, 3b) has model discrimination information by short-circuiting the empty pins selected according to the model from the plurality of empty pins of the connector 8i. That is, the model of the film camera 3a is M company type 1, and the cable 5a of the film camera 3a is short-circuited between the vacant pins 1 and 3 of the connector 8i, and the film camera 3b is type F company type 2 In this cable 5b, the empty pins 7 and 8 of the connector 8i are short-circuited by short-circuit lines 25a and 25b.

  On the other hand, on the synchronizer body 1 side, the pin of the connector 8o corresponding to one side of the vacant pins forming the short-circuited set of the connector 8i, in this case, the pins 1 and 8 are grounded, and the M company 1 type film The third pin of the connector 8o corresponding to the shorted pin of the cable 5a of the camera 3a is the terminal RB6 of the PIC15, and the seventh pin of the connector 8o corresponding to the shorted pin of the cable 5b of the F company 2 type film camera 3b is the PIC15. Is connected to the terminal RB7.

  In the above configuration, when the M company 1 type film camera 3a is used, when the connector 8i of the cable 5a for the M company is connected to the connector 8o, the terminal RB6 of the PIC 15 corresponding to the 3 pin becomes L level, Since the terminal RB7 of the PIC 15 is at the H level, the PIC 15 can determine the model of the film camera 3a connected via the cable 5a based on the signal levels of these terminals.

  Similarly, when the F company type 2 film camera 3b is used, when the connector 8i of the cable 5a is connected to the connector 8o, the terminal RB7 of the PIC 15 corresponding to the 7-pin becomes L level, and the terminal of the PIC 15 Since RB6 is at the H level, the PIC 15 can determine the model of the film camera 3b connected via the cable 5b based on the signal levels of these terminals.

  Similarly to the above, when the film camera 3 other than the model described above can be used, a pair of empty pins different from the above is short-circuited, and a signal corresponding to one of the pins By connecting the line to the terminal of the PIC 15, it is possible to automatically distinguish between these models.

  However, since there are not many types of film cameras 3 used by experts in photo studios and the like, when the number of models used in the synchronous photographing apparatus of the present invention is limited to, for example, about three types, film cameras of other models than the above are used. In the cable 3 for 3, the terminal RB6 and the terminal RB7 of the PIC 15 are both at the H level even if they are connected unless the above-described pair of empty pins is short-circuited. Automatic model discrimination can be performed.

  The model discrimination means of the film camera 3 described above gives model discrimination information by short-circuiting the empty pins selected according to the model from the plurality of empty pins of the connector 8i to the cable 5 of the film camera 3. The model discriminating means of the synchronization device main body 1 is configured to detect and detect the signal of the model discrimination line connected to the pin of the connector 8o on the synchronization device main body 1 side corresponding to the short-circuited empty pin. Projections and the like are provided at positions selected from a plurality of locations such as around the connector on the cable 5 side of the film camera 3, and the positions of these projections and the like are detected by a detection device provided on the connector 8o on the synchronization device main body 1 side. Thus, it can be configured to automatically determine the model.

  In the figure, reference numeral 26 denotes a lamp indicating that the power is on, and 27 denotes a clock crystal.

  In the above configuration, when performing synchronous shooting of the film camera 3 and the digital camera 4 using the synchronous shooting device of the present invention, the cables 13, 5, and 9 of the remote switch 2, the film camera 3, and the digital camera 4, respectively. The connectors 14o, 8i, 12i are connected to the connectors 14i, 8o, 12o on the synchronizer main body 1 side to turn on the power.

  As described above, the synchronization apparatus main body 1 determines the model by the cable 5 configured for each model of the film camera 3, and the information is stored in a predetermined processing storage unit in the PIC 15.

  Next, the photographer operates the selection operation switch 18 constituting the delay time selection means according to the model of the digital camera 4 to be used, and selects the contacts 17a to 17e to be electrically connected to the common contact 17f. In the operation portion of the selection operation switch 18, indices such as serial numbers 1 to 5 are displayed corresponding to these contacts 17a to 17e, and a correspondence table between the models of the digital camera 4 and the indices is used. Thus, it is possible to reliably select the delay time.

  In the above configuration, the synchronous shooting operation in the present invention will be described with reference to the simplified time chart shown in FIG.

  That is, when the common push button of the remote switch 2 is pushed, the contact 20a side is first grounded and an L level autofocus signal is generated. This autofocus signal is transmitted to both the film camera 3 and the digital camera 4 via the respective cables 5 and 9 as described above, and each autofocus function starts operating.

  Next, when the common push button of the remote switch 2 is further pushed, the autofocus signal remains unchanged and an L level remote shutter release signal is generated. The remote shutter release signal is input to the terminal RB5 of the PIC 15 as described above, and the synchronous shooting operation of the PIC 15 is started.

  That is, when a remote shutter release signal is input from the remote switch 2, the PIC 15 first sets the terminal RA1 to L level and turns on the remote shutter release output circuit 19a. When the remote shutter release output circuit 19a is turned on, the 2 pins of the connectors 8i and 8o become the same potential as the 4 pins, and the remote shutter release signal thereby is transmitted to the film camera 3a through the cable 5 (5a, 5b), and the film camera 3a Remote shutter release operation starts.

  On the other hand, the PIC 15 to which the remote shutter release signal is inputted from the remote switch 2 is the model determined by the model determining means and the delay time selected by the index by the delay time selecting means, that is, the state of the selection operation switch 18 of the delay time selecting means. From this, the delay time of the remote shutter release signal of the digital camera relative to the remote shutter release signal of the film camera 3 is derived, and after this delay time has elapsed, the remote shutter release signal of the digital camera 4 is generated from the terminal RA0. This remote shutter release signal is input to the delay time adjusting means 21, and after a delay time adjusted by the variable resistor 23 of the preceding monostable multivibrator 22a, a predetermined remote shutter release signal is sent from the subsequent monostable multivibrator 22b. This remote shutter release signal is converted as an L level signal via a switch circuit, and is transmitted to the digital camera 4 via the cable 9 via the 3 pins of the connectors 12i and 12o. Release operation starts.

  As described above, in the present invention, the delay of the remote shutter release signal of the digital camera 4 with respect to the remote shutter release signal of the film camera 3 is determined based on the determined model of the film camera 3 and the delay time selected by the index by the delay time selection means. The time can be set according to the model, and the shutters of both the film camera 3 and the digital camera 4 are generated by generating remote shutter release signals corresponding to the film camera 3 and the digital camera 4 with a delay time therebetween. It is possible to absorb the difference in operating characteristics and perform shooting with the two accurately synchronized. In the synchronous shooting operation described above, as in the case shown in the time chart of FIG. 9, a strobe is emitted in response to the opening operation of the shutter of the film camera 3 or, depending on the case, the shutter of the digital camera 4. By causing the strobe to emit light in response to the opening operation, a synchronized photographing operation using the strobe is performed. Such a strobe emitting operation can be incorporated as a function of the synchronization device body 1 of the present invention, or a film. The functions of the camera 3 or the digital camera 4 can be used as they are.

Next, the flow of the synchronous photographing operation in the present invention will be described below with reference to the flowcharts shown in FIGS.
FIG. 3 shows a main routine. First, in step S1, it is determined whether or not the remote shutter release signal of the remote switch 2 is ON. If it is ON, the process proceeds to step S2. The remote shutter release signal is abbreviated as “S” in the flowchart.

  Next, in step S2, first, it is determined whether or not the model determined by the model determining means is the F company 3 type. If YES, the process proceeds to the F company 3 type routine. The process proceeds to step S3.

  Next, in step S3, it is first determined whether or not the model determined by the model determining means is the F company type 2, and if YES, the process proceeds to the F company 2 type routine, and if NO, the following is performed. The process proceeds to step S4.

  Next, in step S4, it is first determined whether or not the model determined by the model determination means is M company type 1. If YES, the process proceeds to the M company type 1 routine. If NO, step S2 is performed. Migrate to

Next, FIG. 4 is a flowchart showing the flow of the company F type 3 routine branched in step S2 of the main routine.
First, in step S5, the film camera 3 turns on the remote shutter release signal together with the autofocus signal (hereinafter abbreviated as AF), but the digital camera 4 turns on only the autofocus signal.

  Next, in step S6, a preset delay of 150 ms is performed for the F company type 3, and the process proceeds to step S7.

  Next, in step S7, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it is selecting CH1. As a result of the determination, if NO, the process proceeds to step S8, and if YES, the process proceeds to step S9, the remote shutter release signal of the digital camera 4 is turned on, and the process proceeds to an end routine. Therefore, in this case, a synchronous shooting operation is performed in which the remote shutter release signal of the digital camera 4 is generated 150 ms after the remote shutter release signal of the film camera 3 is generated.

  Note that CH1 corresponds to the switching contact 17a, and similarly, CH2 to CH5 correspond to the switching contacts 17b to 17e, respectively.

  When branching to step S8 in step S7, in step S8, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it is selecting CH2. As a result of the determination, if NO, the process proceeds to step S10. If YES, the process proceeds to step S11, and after a delay of 33 ms, the process proceeds to step S12, and the remote shutter release signal of the digital camera 4 is turned ON. Transition to end routine. Therefore, in this case, a synchronous photographing operation is performed in which the remote shutter release signal of the digital camera 4 is generated 180 ms (150 + 33) after the remote shutter release signal of the film camera 3 is generated.

  When the process branches to step S10 in step S8, in step S10, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not CH3 is selected. As a result of the determination, if NO, the process proceeds to step S13. If YES, the process proceeds to step S14 and after a delay of 50 ms, the process proceeds to step S15, and the remote shutter release signal of the digital camera 4 is turned ON. Transition to end routine. Therefore, in this case, a synchronous photographing operation is performed in which the remote shutter release signal of the digital camera 4 is generated 200 ms (150 + 50) after the remote shutter release signal of the film camera 3 is generated.

  When branching to step S13 in step S10, in step S13, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it is selecting CH4. As a result of the determination, if NO, the process proceeds to step S16. If YES, the process proceeds to step S17 and after a delay of 70 ms, the process proceeds to step S18, and the remote shutter release signal of the digital camera 4 is turned ON. Transition to end routine. Therefore, in this case, a synchronous photographing operation is performed in which the remote shutter release signal of the digital camera 4 is generated 220 ms (150 + 50) after the remote shutter release signal of the film camera 3 is generated.

  Next, when branching to step S16 in step S13, in step S16, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it is selecting CH5. As a result of the determination, if NO, the process proceeds to step S17, and if YES, the process proceeds to step S19 and after a delay of 90 ms, the process proceeds to step S20, and the remote shutter release signal of the digital camera 4 is turned ON. Transition to end routine. Therefore, in this case, a synchronous shooting operation is performed in which the remote shutter release signal of the digital camera 4 is generated 240 ms (150 + 90) after the remote shutter release signal of the film camera 3 is generated.

  Next, FIG. 5 is a flowchart showing the flow of the F company type 2 routine branched in step S3 of the main routine. This flow is different only in the delay time, and other operations are the same as the routine of FIG. 4. Since this flow is self-evident in the figure, description of the operation is omitted.

FIG. 6 is a flowchart showing the flow of the M company type 1 routine branched in step S4 of the main routine.
First, in step S21, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it is selecting CH1. As a result of the determination, if NO, the process proceeds to step S22. If YES, the process proceeds to step S9, and the digital camera 4 turns on the remote shutter release signal together with the autofocus signal. Only the autofocus signal is turned on.

  Next, in step S24, a preset delay of 15 ms is performed, the process proceeds to step S25, the remote shutter release signal of the film camera 3 is turned ON, and the process proceeds to the end routine. Therefore, in this case, unlike the two models described above, that is, the F company 3 type and the F company 2 type, the remote shutter release of the film camera 3 15 ms after the remote shutter release signal of the digital camera 3 is generated. A synchronous photographing operation in which a signal is generated is performed.

  When the process branches to step S22 in step S21, in step S22, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it is selecting CH2. As a result of the determination, if NO, the process proceeds to step S26, and if YES, the process proceeds to step S27 to turn on the remote shutter release signal in addition to the autofocus signal for both the digital camera 3 and the film camera 4. To the end routine. Therefore, in this case, a synchronous shooting operation is performed in which the remote shutter release signal of the digital camera 3 and the remote shutter release signal of the film camera 3 are generated simultaneously.

  Next, when the process proceeds to step S26 in step S22, in step S22, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it selects CH3. As a result of the determination, if NO, the process proceeds to step S28, and if YES, the process proceeds to step S29. In step S29, the film camera 3 turns on the remote shutter release signal together with the autofocus signal (hereinafter abbreviated as AF), but the digital camera 4 turns on only the autofocus signal.

  Next, the process proceeds to step S30, and after a delay of 8 ms, the process proceeds to step S31, the remote shutter release signal of the digital camera 4 is turned ON, and the process proceeds to an end routine. Therefore, in this case, a synchronous shooting operation is performed in which the remote shutter release signal of the digital camera 4 is generated 8 ms after the remote shutter release signal of the film camera 3 is generated.

  Next, when the process proceeds to step S28 in step S26, in step S28, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it selects CH4. As a result of the determination, if NO, the process proceeds to step S32, and if YES, the process proceeds to step S33. In step S33, the film camera 3 turns on the remote shutter release signal together with the autofocus signal (hereinafter abbreviated as AF), but the digital camera 4 turns on only the autofocus signal.

  Next, the process proceeds to step S34, and after a delay of 50 ms, the process proceeds to step S35, the remote shutter release signal of the digital camera 4 is turned on, and the process proceeds to an end routine. Therefore, in this case, a synchronous shooting operation is performed in which the remote shutter release signal of the digital camera 4 is generated 50 ms after the remote shutter release signal of the film camera 3 is generated.

  Next, when the process proceeds to step S32 in step S28, in step S32, the operation state of the selection operation switch 18 of the delay time selection means is determined, and it is determined whether or not it selects CH5. As a result of the determination, if NO, the process proceeds to step S21, and if YES, the process proceeds to step S36. In step S36, the film camera 3 turns on the remote shutter release signal together with the autofocus signal (hereinafter abbreviated as AF), but the digital camera 4 turns on only the autofocus signal.

  Next, the process proceeds to step S37, and after a delay of 60 ms, the process proceeds to step S38, the remote shutter release signal of the digital camera 4 is turned ON, and the process proceeds to an end routine. Therefore, in this case, a synchronous shooting operation is performed in which the remote shutter release signal of the digital camera 4 is generated 60 ms after the remote shutter release signal of the film camera 3 is generated.

  As described above, the delay time setting means operates the selection operation switch 18 according to the model of the digital camera 4 to be used. As for the main models, as described above, the model of the digital camera 4 is used. By using a correspondence table etc. with the index, the delay time can be selected reliably, but if the actual shutter characteristics are slightly different when selected according to the model, Fine adjustment can be performed by the delay time adjusting means described above, and for example, a delay time can be added up to about 20 ms. This delay time adjusting means can be used for adjusting individual differences of the same model, and can also be used for fine adjustment when the digital camera 4 that is not assumed is used.

  FIG. 7 collectively shows the delay time of the remote shutter release signal of the digital camera 4 with respect to the remote shutter release signal of the film camera 3 in the routine of each model of the film camera 3 described above.

Next, FIG. 8 shows the operation flow of the end routine.
In step S39, the end routine determines whether or not a remote shutter release signal is input from the remote switch 2, that is, whether or not the pushing operation of the remote switch 2 is stopped. If the result of determination is NO, that is, if the remote shutter release signal is not input from the remote switch 2, the process proceeds to the next step S40, and in this step S40, it is determined whether or not the delay time adjusting means is operating. To do. Whether or not this operation is in progress is determined by the output signal of the subsequent monostable multivibrator 22b input to the terminal RA3 of the PIC15.

  As a result of the determination, if the delay time adjusting means is operating, the process returns to step S40, and thereafter, the operation of the delay time adjusting means is monitored by a loop operation. If the delay time adjusting means stops after the predetermined operation as a result of the determination, the process proceeds to step S41, where the remote shutter release signals of both the film camera 3 and the digital camera 4 are turned OFF to stop the predetermined photographing operation. Thereafter, after a delay of 5 ms in step S42, the process proceeds to step S43, where the autofocus signals of both the film camera 3 and the digital camera 4 are turned off to complete the photographing operation.

  Since the present invention is as described above, the synchronized shooting of a film camera and a digital camera has a number of features as described below and has great industrial applicability.

  1. In the present invention, the synchronization device main body determines the model by the film camera cable connected to the remote release function output unit, and supports the delay time of the delay time setting means according to the model of the digital camera connected through the cable. By selecting the index to be used, the shutter operation characteristics of the film camera and the digital camera are input to the synchronization device body.

  2. Thus, the synchronizer body sets the delay time of the remote shutter release signal of the digital camera relative to the remote shutter release signal of the film camera according to the model from the determined model and the delay time selected by the index by the delay time selection means. A remote shutter release signal is generated at the output part of the remote release function corresponding to the film camera and the digital camera, respectively, with a delay time, thereby absorbing the difference in shutter operation characteristics between the film camera and the digital camera. Thus, it is possible to perform shooting in which both are accurately synchronized.

  3. Since the shutter operation characteristics of digital cameras vary considerably depending on the manufacturer and model, providing a delay time adjusting means in addition to the delay time selecting means described above makes it possible to deal with various types of digital cameras.

  4). The film camera model is determined by providing model identification information by short-circuiting the unused pins selected according to the model from the plurality of unused pins of the cable connector. If it is configured to detect the signal of the model identification line connected to the connector pin on the synchronizer body side corresponding to the short pin that is short-circuited, the film camera model can be automatically identified reliably. Good usability.

It is explanatory drawing which shows an example of the whole structure of the synchronous imaging device which concerns on this invention. It is a time chart which simplifies and shows the operation | movement of synchronous imaging | photography in this invention. It is a flowchart which shows the routine which implement | achieves operation | movement of the synchronous imaging device in this invention. It is a flowchart which shows the other routine which implement | achieves operation | movement of the synchronous imaging device in this invention. It is a flowchart which shows other routine which implement | achieves operation | movement of the synchronous imaging device in this invention. It is a flowchart which shows further another routine which implement | achieves operation | movement of the synchronous imaging device in this invention. The delay time of the remote shutter release signal of the digital camera with respect to the remote shutter release signal of the film camera is collectively shown. It is a flowchart which shows other routine which implement | achieves operation | movement of the synchronous imaging device in this invention. It is a time chart which shows the operation | movement at the time of performing synchronous imaging | photography with a film camera and a digital camera without using the apparatus of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Synchronizer main body 2 Remote switch 3 (3a, 3b) Film camera 4 Digital camera 5, 9, 13 Cable 6, 10 Remote release function input part 7, 11 Remote release function output part 8 (8i, 8o) Connector 9 Cable 12 (12i, 12o) Connector 14 (14i, 14o) Connector 15 PIC
16 voltage monitoring circuits 17a to 17e switching contact 18 selection operation switch 19a remote shutter release output circuit 19b autofocus output circuits 20a, 20b, 20c contact 21 delay time adjusting means 22a, 22b monostable multivibrator 23 variable resistor 24 switch circuit 25a 25b Short-circuit wire 26 Power lamp 27 Crystal

Claims (6)

The synchronization device main body, the remote switch, and the cable for connecting the remote release function input unit of each of the film camera and the digital camera and the remote release function output unit of the synchronization device main body via a connector Includes a model discriminating means for discriminating the model by a film camera cable connected to the remote release function output unit, a delay time selecting means for selecting a delay time, a model discriminated by the model discriminating means, and a delay time selecting means. The delay time setting means to set the delay time of the remote shutter release signal of the digital camera relative to the remote shutter release signal of the film camera from the delay time selected in, and the remote release function output unit corresponding to the film camera and the digital camera respectively. Set by the delay time setting means Synchronous photography device of the film camera and a digital camera, characterized in that a remote shutter release signal generating means for separating the delay time generating remote shutter release signal of each was. Adjustable delay time of digital camera remote shutter release signal relative to film camera remote shutter release signal by adding adjustable delay time between digital camera remote shutter release signal generating means and corresponding remote release function output unit The synchronized photographing apparatus for a film camera and a digital camera according to claim 1, further comprising a delay time adjusting unit capable of adjusting the delay time. The delay time adjustment means is composed of two cascaded monostable multivibrators, which can adjust the delay time added by adjusting the pulse width of the previous monostable multivibrator, and the remote shutter release by the subsequent monostable multivibrator. 3. A synchronous photographing apparatus for a film camera and a digital camera according to claim 2, wherein a signal is generated. The film camera cable has model identification information by short-circuiting the unused pins selected according to the model from a plurality of unused pins of the connector, and the model identification means of the synchronizer body 2. The synchronous photographing apparatus for a film camera and a digital camera according to claim 1, wherein the apparatus performs detection by detecting a signal of a model discrimination line connected to a pin of a connector on the corresponding synchronizer body side. The remote release function includes an autofocus function in addition to the remote shutter release function, and the remote switch is provided with a switch section corresponding to the autofocus function and a switch section corresponding to the remote shutter release function. The synchronized photographing apparatus for a film camera and a digital camera according to claim 1. 2. The film camera according to claim 1, wherein the remote switch has a configuration in which an operation range of the remote shutter release function is set inside an operation range of the autofocus function when a common push button is pressed. Synchronous shooting device for digital cameras.

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