JP2010068288A - Control method, program, and storage medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the load of an imaging apparatus in remote control of the imaging apparatus. <P>SOLUTION: This control method includes: a first management step of managing a command to be used for AF processing in the imaging apparatus, and a second management step of managing a command to be used for imaging processing in the imaging apparatus. When the commands for the AF processing are redundant in the first management step, command decimation is performed to the commands for the AF processing, the decimation being not performed when the commands for the imaging processing are redundant in the second management step. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a control method for controlling an imaging apparatus, a program for executing the control method, and a storage medium for storing the program.

  Conventionally, a personal computer equipped with a display and a pointing device such as a mouse is connected to an imaging apparatus by a cable, and the imaging apparatus is remotely controlled by the personal computer. A system is disclosed in which a personal computer remotely controls half-push control (control of shooting preparation operations such as AF and AE) and full-push control (control of shooting operations) of the imaging apparatus (see Patent Document 1). .

In such a remote control system, when the mouse is moved over a shooting button displayed on a display via a mouse, a command for instructing half-press control of the imaging device is transmitted to the imaging device. Then, the imaging device that has received the command executes half-press control. In addition, when a shooting button displayed on the display is clicked, a command for instructing full press control of the imaging apparatus is transmitted to the imaging apparatus. Then, the imaging device that has received the command executes full-press control. After the shooting operation is executed by the imaging apparatus, the acquired captured image data is transmitted to the personal computer by the imaging apparatus.
JP 2007-210502 A

  In the above remote control system, there is a problem that a large amount of commands for instructing half-press control is sent to the camera by moving the mouse vigorously on the shooting button, which increases the load on the camera. The same applies to problems relating to other commands such as a large number of commands instructing full-press control by mouse click of the shooting button being sent to the camera.

  The present invention has been made in view of such problems, and aims to reduce the load on the camera by making appropriate control signals to be sent to the imaging device, such as commands for half-press control and full-press control. With the goal.

  In order to solve the above-described problems, a technical feature of the present invention is a control method for remotely controlling an imaging apparatus, the command for causing the imaging apparatus to perform AF processing, and the imaging A management step for managing a command for causing the apparatus to perform shooting processing. In the management step, if there is a duplicate command in the command for performing the AF processing, the command is thinned, and the shooting processing is performed. If there are duplicate commands in the command to be executed, the command is not thinned out.

  According to the present invention, it is possible to reduce the load on the camera.

(Embodiment 1)
FIG. 1 is a diagram showing an example of a schematic configuration of a remote control system according to Embodiment 1 of the present invention, and FIG. 2 is a block diagram of the remote control system. Reference numeral 100 denotes a PC (Personal Computer) (hereinafter referred to as a PC) as an example of a control apparatus, and reference numeral 200 denotes a digital camera as an example of an imaging apparatus. Reference numeral 300 denotes a USB cable (Universal Serial) (hereinafter, USB) which is an example of a connection cable for connecting the PC 100 and the digital camera 200. These will be described in detail below.

<USB cable 300>
The USB cable 300 includes a data line for transmitting data bidirectionally, a strobe signal line for transferring a strobe signal, a power supply line, and the like.

  In the data line, a protocol for controlling the digital camera 200 connected to the PC 100 is prepared. With this protocol, it is possible to transfer various data and transmit / receive commands 700 between the USB compatible PC 100 and the digital camera 200.

  The strobe signal line is a line for transmitting a strobe signal, which is a signal indicating that data is being output, to a device receiving data from the device transferring data. Data transfer is performed at both rising and falling edges of the strobe signal. In an apparatus for receiving data, transmitted data is generated by a data line and a strobe signal line.

  The power supply line is a line for supplying power from the PC 100 to the digital camera 200 as necessary.

  Note that the connection cable is not limited to the USB cable. For example, a connection cable conforming to the IEEE 1394 standard having a line for transmitting image data, audio data, and auxiliary data can be considered. Further, although the connection cable is used in the above embodiment, the communication between the PC 100 and the digital camera 200 may be performed by wireless communication.

<Digital camera 200>
The digital camera 200 is a video source that can transmit video data, audio data, and auxiliary data to the PC 100 via the USB cable 300. Also, the digital camera 200 receives a control command 700 from the PC 100 via the USB cable 300, and executes processing according to the command 700.

  More specifically, the digital camera 200 includes a CPU 201, a memory 202, a recording unit 203, a communication unit 204, an image processing unit 205, a display unit 206, an operation unit 207, and an imaging unit 208, as shown in FIG. The photographing preparation process and the photographing process are executed.

  The CPU 201 controls the overall operation of the digital camera 200 in accordance with a computer program stored in the memory 202. Further, the CPU 201 acquires information related to the PC 100 from the PC 100 via the USB cable 300 and stores it in the memory 202. The work area of the CPU 201 is not limited to the memory 202 but may be an external storage device such as a hard disk device.

  The memory 202 is a memory that functions as a work area for the CPU 201 as described above. It is also a memory that stores various values, data, and information used by the CPU 201. The information stored in the memory 202 includes a computer program for controlling the digital camera 200, predetermined image data and icons displayed on the display unit 206, and the like.

  The communication unit 204 has a terminal for connecting the USB cable 300. The communication unit 204 transmits image data, audio data, and auxiliary data generated by the CPU 101 to the PC 100 via the USB cable 300. The communication unit 204 receives a command 700 transmitted from the PC 100 via the USB cable 300. When receiving the command 700 from the PC 100, the communication unit 204 supplies the received command 700 to the CPU 101.

  The operation unit 207 is a user interface for operating the digital camera 200 and has a plurality of buttons for operating the digital camera 200. An instruction from the user is input to the CPU 201 via the operation unit 207. Each button in the operation unit 207 includes a switch, a touch panel, and the like. The operation unit 207 includes a shutter button, a power button, a start / stop button, a mode change button, a menu button, a cross button, a SET button, and the like.

  The shutter button has two states, S1 in which the shutter button is half-pressed and S2 in which the shutter button is fully pressed.

  The power button is a button for instructing the CPU 201 to change the digital camera 200 to a power-on (ON) state or a power-off (OFF) state. The power-on state is a state in which necessary power can be supplied to the entire digital camera 200 from a power source (not shown) (battery, AC power source, etc.). The power-off state is a state in which power supply from a power source (not shown) (battery, AC power source, etc.) to a part or all of the digital camera 200 is stopped.

  The start / stop button is a button for instructing the CPU 201 to start or pause recording of image data or the like generated by the imaging unit 208 on a recording medium. The mode change button is a button for instructing the CPU 201 to change the operation mode of the digital camera 200 to any one of a normal shooting mode, a playback mode, a continuous shooting mode, a bulb shooting mode, a mirror-up shooting mode, and the like.

  The menu button is a button for instructing the CPU 201 to display or hide the menu screen of the digital camera 200. The menu screen of the digital camera 200 includes a menu screen for controlling the digital camera 200 and a menu screen for changing settings of the digital camera 200. These menu screens are stored in the memory 202.

  The operation unit 207 includes a play button, a stop button, a pause button, a fast forward button, a rewind button, and the like. These buttons are buttons for instructing the CPU 201 to play (play), stop (pause), fast forward (fast forward), and rewind (rewind) the image data recorded on the recording medium. is there.

  The imaging unit 208 includes an imaging element, an A / D conversion unit, and an optical system. The optical system is a photographing lens group, and includes a variator lens that raises a photographing magnification, a focusing lens that adjusts a focal point, a diaphragm that adjusts a photographing light amount, a drive circuit thereof, and the like. The imaging device converts subject light incident through the optical system into an image signal that is an electrical signal. Examples of the image sensor include a CCD image sensor and a CMOS sensor. The A / D converter converts an image signal (analog data) output from the image sensor into digital data (image data) and outputs the digital data (image data) to the image processor 205.

  The image processing unit 205 performs image processing such as pixel interpolation processing and color conversion processing on the image data output from the imaging unit 208 or the image data output from the recording unit 203. The image processing unit 205 includes a compression / decompression circuit, and is a compression / decompression circuit that compresses / decompresses image data by adaptive discrete cosine transform (ADCT) or the like, and reads the image data stored in the memory 202. The image data is compressed or decompressed. Further, the image processing unit 205 performs arithmetic processing using the image data output from the imaging unit 208. Based on the calculation result, the CPU 101 controls TTL (through the lens) AF processing, AE processing, flash pre-flash processing, and TTL auto white balance processing.

  The display unit 206 is configured by a liquid crystal display or the like. The display unit 206 displays the image data generated by the imaging unit 208 or the image data reproduced from the recording medium by the recording unit 203.

  Here, the shooting preparation process is a process performed in the digital camera 200 when the shutter button included in the operation unit 207 of the digital camera 200 is half-pressed to be in the state of S1. In this process, the CPU 201 controls the image sensor, the A / D converter, and the optical system of the imaging unit 208, and performs AF processing and AE processing. The shooting preparation process includes, for example, a flash pre-flash (hereinafter referred to as “EF”) process, an auto white balance (hereinafter referred to as “AWB”) process, and an image stabilization process.

  The AF process is a process in which the CPU 201 controls the position of the focusing lens included in the imaging unit 208, and is a process for detecting the in-focus position of the focusing lens and adjusting the position of the focusing lens.

  Specifically, the CPU 201 first controls the imaging lens to acquire a plurality of image signals while driving the focusing lens from a position corresponding to infinity to a position corresponding to a close distance set in each operation mode. . Then, measurement data such as the focusing lens position (focusing position) and / or setting parameters where the high-frequency component extracted from the image signal is the largest are stored in the memory 202 and controlled to adjust the focusing lens position.

  The AE process is a process for obtaining a photometric value using a calculation result in the image processing unit 205 and adjusting the exposure appropriately.

  More specifically, the image data output from the imaging unit 208 is divided into a plurality of areas (for example, 16 × 16) by the image processing unit 205, and RGB signals are integrated for each divided area. The integrated value is provided to the CPU 201. The CPU 201 detects the brightness of the subject (subject brightness) based on the integrated value, and calculates an exposure value suitable for shooting. An aperture value and a shutter speed are determined according to the obtained exposure value, and the CPU 201 controls the image sensor and the optical system in accordance with this to obtain an appropriate exposure amount. If it is determined that the exposure is appropriate, the measurement data and / or setting parameters are stored in the memory 202.

  The EF process is a process performed when it is determined that the flash is necessary according to the result of the CPU 201 performing the AE process and determining the aperture value and the shutter speed. If the CPU 201 determines that a flash is necessary, the flash flag is set and the flash is charged. It also has an AF auxiliary light projecting function and a flash light control function.

  The AWB process is a process performed to obtain an appropriate color balance of the flash photographed image by obtaining the color temperature of the external light and the ratio of the light quantity of the external light and the flash light from the recorded image. The image processing unit 205 calculates an average integrated value for each color of the RGB signals for each divided area, and provides the calculation result to the CPU 201. The CPU 201 obtains the integrated value of R, the integrated value of B, and the integrated value of G, and obtains the ratio of R / G and B / G for each divided area. Then, the light source type is determined based on the distribution of these R / G and B / G values in the color space of the R / G and B / G axis coordinates, etc., and R, G, and B are determined according to the determined light source type. The white balance correction value for the signal is controlled to correct the signal of each color channel.

  The shooting preparation process has been described above, but in addition to these processes, a process that is preferably executed before the shooting process may be performed as the shooting preparation process. Further, the AWB process may be performed between the shooting preparation process and the shooting process.

  Next, the photographing process will be described.

  The photographing process is a process performed when the shutter button of the digital camera 200 is fully pressed to enter the state of S2. In this process, the analog data output from the image sensor in the imaging unit 208 is converted into digital data by the A / D conversion unit, then compressed by the image processing unit 205, and the image data is written to the recording unit 203. .

<PC100>
The PC 100 displays video data transmitted from the digital camera 200 via a USB cable 300 on a display device, and outputs audio data from a speaker. Further, the PC 100 generates a command 700 for controlling the digital camera 200 in response to an input from the user, and transmits the command 700 to the digital camera 200 via the USB cable 300.

  As illustrated in FIG. 2, the PC 100 includes a CPU (Central Processing Unit) 101, a memory 102, a communication unit 104, a display unit 105, and an operation unit 106.

  The CPU 101 controls the operation of the PC 100 according to the computer program stored in the memory 102. In addition, the CPU 101 has a timer (not shown), and measures the elapsed time of processing executed by each unit.

  The memory 102 also functions as a main memory of the CPU 101 and stores data from the digital camera 200 received from the communication unit 104. The memory 102 also stores a plurality of icons for notifying the user of the state of the PC 100, a computer program for controlling the operation of the PC 100, and the like. A menu screen to be displayed on the display unit 105 is also stored.

  The communication unit 104 has a terminal for connecting the USB cable 300. The communication unit 104 can receive image data, audio data, and auxiliary data transmitted from the digital camera 200 via the USB cable 300. Image data transmitted from the digital camera 200 is stored in the memory 102 and displayed on the display unit 105. Also, audio data transmitted from the digital camera 200 is output from a speaker unit (not shown). In addition, auxiliary data transmitted from the digital camera 200 is supplied to the CPU 101.

  The display unit 105 includes a display device such as a liquid crystal display. The display unit 105 can display image data supplied from at least one of the memory 102 and the communication unit 104. The display unit 105 can also display a menu screen that is a graphical user interface stored in the memory 102. The menu screen includes a PC control screen for controlling the PC 100, a PC setting screen for changing settings of the PC 100, a camera control screen 400 for controlling the digital camera 200, and the like. Details of the camera control screen 400 will be described later.

  When these menu screens are displayed on the display unit 105, the CPU 101 displays a mouse cursor (an arrow-shaped icon) 500 superimposed on the menu screen.

  Further, the display unit 105 displays the image data supplied from the communication unit 104 in a predetermined area of the camera control screen 400 supplied from the CPU 101.

  The operation unit 106 is a user interface for operating the PC 100. The operation unit 106 includes a mouse 106a, a pointing device such as a tablet and a trackball, and a keyboard 106b as operation means for operating the PC 100. When the user operates these pointing devices, the mouse cursor 500 superimposed on the menu screen can be operated on the menu screen.

  On the menu screen, the mouse cursor 500 moves on the menu screen according to the position information of the pointing device, and when the pointing device is pressed, the mouse cursor 500 performs processing according to the detected predetermined area.

<Camera control screen 400>
FIG. 3 shows a camera control screen 400, which is an example of a menu screen, and is configured on a window system that is standardly adopted by the OS of a personal computer.

  The camera control screen 400 is a window for remotely controlling the camera. There are a view area 401 for displaying image data, a status area 402 for displaying the state of the remote control system as character information, a shutter button 403, a parameter area 404 for displaying parameters of the imaging apparatus, and the like.

  A view area 401 displays a live view video continuously received from the digital camera 200 by the communication unit 104 of the PC 100 or a still image received by a shooting operation.

  In the status area 402, “shootable” is displayed as the state of the remote control system. However, in other remote control system states, “capable of shooting”, “preparing for shooting”, and “during shooting process” are displayed.

  The shutter button 403 performs shooting processing in two states, S1 in which the shutter button is half-pressed and S2 in which the shutter button is fully pressed. When the operation mode of the digital camera 200 is the normal shooting mode, when the mouse cursor 500 is moved onto the shutter button 403, the PC 100 instructs the digital camera 200 to start shooting preparation processing. Further, when the operation mode of the digital camera 200 is the normal shooting mode, when the mouse cursor 500 is clicked with the shutter button 403 being on, the PC 100 instructs the digital camera 200 to start a series of shooting processing operations. . The shooting preparation process performed when the shutter button is in the state S1 and the shooting process performed when the shutter button is in the state S2 are as described above.

  The parameter area 404 displays an operation mode, shutter speed, aperture value, white balance value, and the like. These values are included in auxiliary data received from the digital camera 200. The parameter area 404 may display auxiliary data other than this. When the value on the parameter area 404 is changed by the operation, the CPU 101 causes the communication unit 104 to generate a command 700 for setting auxiliary data and adds the command 700 to the transmission command queue 600. Here, the transmission command 710 included in the command 700 for setting auxiliary data is referred to as an auxiliary data setting command. The processing of the transmission command queue 600 will be described later. Thereby, the parameters of the digital camera are changed.

  The CPU 101 performs control so that data received from the digital camera 200 by the communication unit 104 is displayed in the view area 401, the status area 402, and the parameter area 404, respectively.

  When an instruction such as mouse over or click is given in a predetermined area such as the shutter button 403 or the parameter area 404, the PC 100 generates a command for controlling each of the digital cameras 200. .

<Operation of Digital Camera 200 upon Receiving Command 700 from PC 100>
Next, processing performed by the digital camera 200 according to the first embodiment will be described with reference to FIGS. 1, 2, and 4. FIG. 4 is a flowchart illustrating an example of processing performed by the digital camera 200 according to the first embodiment. 4 is a process executed when the PC 100 and the digital camera 200 are connected via the USB cable 300 and the PC 100 and the digital camera 200 are in a power-on state. Note that the processing shown in the flowchart of FIG. 4 is controlled by the CPU 201 executing a computer program stored in the memory 202.

  In step S101, when the operation mode of the digital camera 200 is set to the normal shooting mode by the operation unit 207, the CPU 201 causes the communication unit 204 to generate an operation mode signal indicating the normal shooting mode. Then, an instruction is sent to the communication unit 104 of the PC 100 via the USB cable 300.

  In step S102, the CPU 201 determines whether or not the communication unit 204 has received a command 700 for controlling shooting preparation. Here, the transmission command 710 included in the command 700 for controlling the shooting preparation is referred to as a shooting preparation command. When the CPU 201 determines that the command 700 including the shooting preparation command has been received, the CPU 201 sets a shooting preparation flag in the memory 202. Then, the CPU 201 issues an instruction to execute the shooting preparation process (step S103).

  When the CPU 201 determines that the command 700 including the shooting preparation command has not been received, the communication unit 204 determines again whether or not the command 700 including the shooting preparation command has been received.

  If shooting preparation processing is performed in step S103, the process proceeds to step S404.

  In step S <b> 104, the CPU 201 determines whether the communication unit 204 has received a command 700 for controlling shooting from the PC 100. Here, the transmission command 710 for controlling imaging included in the command 700 is referred to as an imaging command.

  If the CPU 201 determines that the communication unit 204 has received the command 700 including the shooting command, the CPU 201 sets the shooting flag in the memory 202 and issues an instruction to execute the shooting process (step S105). When the shooting process is performed, the CPU 201 resets the shooting preparation flag and the shooting flag in the memory 202.

  On the other hand, if the communication unit 204 determines that the command 700 including the shooting command has not been received, the CPU 201 resets the shooting preparation flag in the memory 202 and returns to step S102.

  In step S <b> 106, the CPU 201 causes the communication unit 204 to generate a preparation completion signal indicating that image data transmission preparation has been completed, and instructs the PC 100 to transmit the preparation completion signal. After the preparation completion signal is transmitted to the PC 100, the CPU 201 reads the image data from the recording unit 203 and instructs the communication unit to transmit the read image data to the PC. And the process of the digital camera 200 performed by this flowchart is complete | finished.

<Operation of PC 100 when Sending Command 700 to Digital Camera 200>
Next, processing performed by the PC 100 according to the first embodiment will be described with reference to FIGS. 1, 2, and 5. FIG. 5 is a flowchart illustrating an example of processing performed by the PC 100 according to the first embodiment. 5 is a process executed when the PC 100 and the digital camera 200 are connected via the USB cable 300 and the PC 100 and the digital camera 200 are in the power-on state. Note that the processing shown in the flowchart of FIG. 5 is controlled by the CPU 101 executing a computer program stored in the memory 102.

  When the communication unit 104 receives an operation mode signal indicating the normal shooting mode from the digital camera 200, the CPU 101 sets an operation mode flag in the memory 102 to “normal shooting mode”.

  Thereafter, the CPU 101 reads the camera control screen 400 from the memory 102 and displays it on the display unit 105. The MODE in the parameter area 404 of the camera control screen 400 displayed on the display unit 105 is set to normal shooting, and “shootable” is displayed in the status area 402 of the camera control screen 400. When the operation mode of the digital camera 200 is set to the continuous shooting mode, the MODE of the camera control screen 400 displayed on the display unit 105 is set to continuous shooting, and when the operation mode is set to the bulb shooting mode, MODE is set to bulb photography. When the operation mode of the digital camera 200 is set to the mirror-up shooting mode, the MODE is set to mirror-up shooting.

  In step S <b> 201, the CPU 101 determines whether the mouse cursor 500, which is an example of a determination unit, has been detected (mouse over) on the area of the shooting button 403. When the CPU 101 does not detect the mouse cursor 500 on the shooting button 403 area, the CPU 101 repeats the determination whether the mouse cursor 500 is detected on the shooting button 403 area.

  In step S <b> 201, when the CPU 101 detects the mouse cursor 500 on the area of the shooting button 403, the CPU 101 causes the communication unit 104 to generate a command 700 including a shooting preparation command and instructs the transmission command queue 600 to add. The processing of the transmission command queue 600 will be described later.

  In step S <b> 203, the CPU 101 determines whether the mouse cursor 500 is continuously detected (during mouse over) on the area of the shooting button 403.

  When the CPU 101 determines that the mouse cursor 500 is detected on the area of the shooting button 403, the process proceeds from step S203 to step S204. On the other hand, when the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the flowchart returns from step S203 to step S201.

  In step S <b> 204, the CPU 101 determines whether or not the user has clicked on the button of the mouse 106 a of the operation unit 106 that operates the mouse cursor 500.

  When the CPU 101 determines that the button of the mouse 106a has been clicked, the process proceeds from step S204 to step S205. On the other hand, when the CPU 101 does not determine that the button of the mouse 106a has been clicked, the flowchart returns from step S204 to step S203.

  In step S205, when the mouse 106a is clicked while the mouse cursor 500 is on the shooting button 403, the CPU 101 causes the communication unit 104, which is an example of an instruction unit, to generate a command 700 including a shooting command. Then, it is added to the transmission command queue 600.

  After executing step S <b> 205, a command 700 including a shooting command in the transmission command queue 600 is transmitted to the digital camera 200. The digital camera 200 executes shooting processing and image data transmission as shown in the flowchart of FIG. 4, and the image data is sent to the PC 100.

  In step S <b> 206, the CPU 101 displays the image data sent from the digital camera 200 on the display unit 105. Then, this flowchart ends.

  Thus, when the mouse cursor 500 is moved over the area of the shooting button 403 by operating the mouse 106a, the PC 100 instructs the digital camera 200 to perform shooting preparation processing. Thereafter, when the mouse cursor 500 is over the area of the shooting button 403 where the mouse is over, when the mouse 106a is clicked, the PC 100 instructs the digital camera 200 to perform shooting processing. Further, the image data sent from the digital camera 200 to the PC 100 is displayed.

  In the first embodiment, the digital camera 200 is remotely controlled by confirming the photographing target through a finder (not shown). However, the digital camera 200 displays the live view video on the display unit 105 of the PC 100 and confirms the photographing target. 200 may be remotely controlled.

<Configuration of Transmission Command Queue 600>
Next, the transmission command queue 600 will be described with reference to FIGS.

  FIG. 6 illustrates that command 700 is added from command 1 to command 5 in order, and that there are five commands in transmission command queue 600. The transmission command queue 600 is for processing a plurality of commands 700 in order, and is processed by a first-in first-out method. Further, it is assumed that the command 700 in the transmission command queue 600 can be added, extracted, deleted, rearranged, and managed in sequence.

  FIG. 7 illustrates the command 700.

  Command 700 consists of the following components: A transmission command 710 for controlling the camera, a registration time 720 in which the time added to the transmission command queue 600 is recorded, and a count 730 for managing the same transmission command when a plurality of the same transmission commands are combined into one command. . As described above, the transmission command 710 includes types such as an auxiliary data setting command for controlling the digital camera 200, a shooting preparation command, and a shooting command. By confirming the transmission command 710, it is possible to confirm whether or not the same type of command exists in the transmission command queue 600 when adding a command. Furthermore, by confirming the registration time 720, the elapsed time since the same type of command was added to the transmission command queue 600 when adding a command can be calculated. Further, by confirming the count 730, it is possible to confirm how many commands of the same type are collected.

<Addition of command 700 to transmission command queue 600>
Next, processing for adding a command to the transmission command queue 600 according to the first embodiment will be described with reference to FIG. FIG. 8 is a flowchart illustrating an example of processing for adding a command 700 to the transmission command queue 600 according to the first embodiment.

  The process shown in the flowchart of FIG. 8 is a process executed after the command 700 including the transmission command 710 such as the shooting preparation command and the shooting command is created in the transmission command queue 600 in step S202 and step S205. Alternatively, the process is executed after a command 700 including another transmission command 710 such as an auxiliary data setting command by changing auxiliary data in the parameter area 404 is created in the transmission command queue 600. Note that the processing shown in the flowchart of FIG. 8 is controlled by the CPU 101 executing a computer program stored in the memory 102. In the following description, a shooting preparation command, a shooting command, an auxiliary data setting command, and the like are collectively referred to as a transmission command 710.

  In step S301, it is determined whether a command 700 including a transmission command of the same type as the transmission command to be added to the transmission command queue 600 has already been added to the transmission command queue 600, and whether a predetermined time or more has elapsed since the registration time. Determine. If the condition is met, the process ends without adding the command 700 to the transmission command queue 600. On the other hand, if the condition is not met, the command 700 is generated from the transmission command 710, the registration time 720, and the count 730 and added to the transmission command queue 600. Then, the process ends.

  As described above, in the present embodiment, when a command 700 including the same type of transmission command among commands is repeatedly generated within a certain time, addition of the command 700 is limited in the transmission command queue 600, Thin out. Accordingly, it is possible to solve the problem that a large amount of commands 700 including the same transmission command are transmitted to the digital camera 200 and the load on the digital camera 200 increases.

<Process for Extracting Command 700 from Transmission Command Queue 600>
Next, processing for extracting the command 700 from the transmission command queue 600 according to the first embodiment will be described with reference to FIG.

  The processing shown in the flowchart of FIG. 9 is controlled by the CPU 101 executing a computer program stored in the memory 102.

  In step S401, it is determined whether or not there is a command 700 in the transmission command queue 600. If there is, the process proceeds to step S402. If not, the process returns to S401, and it is determined again whether or not the command 700 exists in the transmission command queue 600.

  In step S402, the command 700 is extracted from the transmission command queue 600, and the process proceeds to step S403.

  In step S403, the CPU 101 controls the communication unit 104 to transmit the command 700 to the digital camera 200, and the process returns to step S401.

  Here, when the transmission command 710 included in the command 700 is a shooting preparation command, “Preparing for shooting” is displayed in the status display area 402. When the transmission command 710 is a shooting command, “in shooting process” is displayed in the status display area 402. When the transmission command 710 is an auxiliary data setting command, the display state of the status display area 402 is not changed.

  In this way, step S401 to step S403 are repeated.

  In the first embodiment, in S301 of the flowchart of FIG. 8, it is determined whether a command to be added to the transmission command queue 600 and a transmission command having the same type are added. Then, it is determined whether or not a certain period of time has elapsed since the registration time, and the same type of command within a certain period of time is not added. However, as an example, as shown in step S <b> 303 in FIG. 10, if the same type of command is added to the transmission command queue 600, the process may be terminated without adding the command to the transmission command queue 600.

  In the first embodiment, it is determined in the flowchart of FIG. 8 whether a predetermined time or more has elapsed since the command registration time. However, if a command of the same type has been added to the send command queue 600, it is determined whether the corresponding command exceeds a certain value, if not, a new command is added, and if it exceeds, a count is added by one. The processing may be terminated. As an example, processing is performed as shown in step S303, step S305, and step S306 in FIG.

  In the first embodiment, the processing is commonly performed for all transmission commands in the flowcharts of FIGS. 8 and 10. However, as an example, as shown in step S304 of FIG. 12, all commands may be added to the transmission command queue for commands including shooting commands that are to be executed in accordance with user instructions.

(Embodiment 2)
In the first embodiment, the normal shooting is described, but in the second embodiment, the bulb shooting is described.

<Bulb photography>
In bulb exposure, the shooting operation starts when the shutter button is pressed, and the shooting operation ends when the shutter button is released, and a series of shooting operations is completed.

  In the state of the shutter button S1, shooting preparation processing equivalent to that in the S1 state of normal shooting is performed, but shooting is started in the state of the shutter button S2 unlike the processing in the state of S2 of normal shooting. Only do. Then, when the shutter button is released, shooting is stopped and a series of shooting operations is completed.

  As an operation at the time of bulb photographing using the camera control screen 400, photographing is started when the photographing button 403 is clicked for the first time, and photographing is stopped when the photographing button 403 is clicked for the second time.

<Camera control screen 400>
Next, the description of the camera control screen 400, which is an example of the menu screen, will be described with reference to FIG.

  The shutter button 403 performs shooting processing in two states, S1 in which the shutter button is half-pressed and S2 in which the shutter button is fully pressed. When the mouse cursor 500 moves onto the shutter button 403 and the operation mode of the digital camera 200 is the bulb shooting mode, the PC 100 instructs the digital camera 200 to start shooting preparation processing. When the mouse cursor 500 is clicked on the shutter button 403 and the operation mode of the digital camera 200 is the bulb shooting mode, the PC 100 instructs the digital camera 200 to start the shooting process. After that, when the mouse cursor 500 is clicked with the shutter button 403 being on and the operation mode of the digital camera 200 is the bulb shooting mode, the PC 100 instructs the digital camera 200 to stop the shooting process. Thereby, a series of photographing operations is completed.

<Operation of Digital Camera 200 upon Receiving Command 700 from PC 100>
Next, with reference to FIG. 13, a description will be given using a flowchart illustrating an example of processing performed by the digital camera 200 according to the second embodiment.

  In step S111, when the operation mode of the digital camera 200 is set to the bulb photographing mode by the operation unit 207, the CPU 201 causes the communication unit 204 to generate an operation mode signal indicating the photographing mode. Then, an instruction is sent to the communication unit 104 of the PC 100 via the USB cable 300. In this case, the flowchart proceeds from step S111 to step S102.

  In step S102, the CPU 201 determines whether or not the communication unit 204 has received a shooting preparation command. If the CPU 201 determines that a shooting preparation command has been received, the CPU 201 sets a shooting preparation flag in the memory 202. In this case, the flowchart proceeds from step S102 to step S103.

  If the CPU 201 determines that it has not received a shooting preparation command, the flowchart returns from step S102 to step S102.

  In step S <b> 103, the CPU 201 issues an instruction to cause the imaging unit 208 to execute shooting preparation processing.

  When the shooting preparation process is performed, the flowchart proceeds from step S103 to step S112.

  In step S <b> 112, the CPU 201 determines whether the communication unit 204 has received a shooting start command including a transmission command for controlling the shooting start from the PC 100. When the CPU 201 determines that the communication unit 204 has received a shooting start command, the CPU 201 sets a shooting flag in the memory 202. In this case, the flowchart proceeds from step S112 to step S113.

  When the CPU 201 determines that the communication unit 204 has not received the shooting start command, the CPU 201 resets the shooting preparation flag in the memory 202. In this case, the flowchart returns from step S112 to step S102.

  In step S <b> 113, the CPU 201 issues an instruction to cause the imaging unit 208 to start shooting processing. In this case, the flowchart proceeds from step S113 to step S114.

  In step S <b> 114, the CPU 201 determines whether or not the communication unit 204 has received a shooting stop command including a transmission command for controlling the shooting stop from the PC 100. In this case, the flowchart proceeds from step S114 to step S115.

  When the CPU 201 determines that the communication unit 204 has not received the shooting stop command, the flowchart returns from step S114 to step S114.

  In step S <b> 115, the CPU 201 issues an instruction to end the shooting process in the imaging unit 208.

  When the photographing process is performed, the CPU 201 resets the photographing preparation flag and the photographing flag in the memory 202. In this case, the flowchart proceeds from step S115 to step S106.

  In step S <b> 106, after the photographing process is completed, the CPU 201 causes the communication unit 204 to generate a preparation completion signal indicating that preparation for transmission of image data is completed, and instructs the PC 100 to transmit the preparation completion signal. After the preparation completion signal is transmitted to the PC 100, the CPU 201 reads the image data from the recording unit 203 and instructs the communication unit to transmit the read image data to the PC. In this case, the processing of the digital camera 200 performed in this flowchart ends.

<Operation of PC 100 when Sending Command 700 to Digital Camera 200>
Next, with reference to FIG. 14, a description will be given using a flowchart illustrating an example of processing performed by the PC 100 according to the second embodiment.

  In step S <b> 201, the CPU 101 determines whether or not the mouse cursor 500 is detected on the area of the shooting button 403. In this case, the flowchart proceeds from step S201 to step S202. When the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the flowchart returns from step S201 to step S201.

  In step S 202, when the CPU 101 detects the mouse cursor 500 on the area of the shooting button 403, the CPU 101 causes the communication unit 104 to generate a shooting preparation command and adds it to the transmission command queue 600. The processing of the transmission command queue 600 will be described later. In this case, the flowchart proceeds from step S202 to step S203.

  In step S203, it is determined whether or not the mouse cursor 500 is over the area where the mouse cursor 500 is over in step S201.

  When the CPU 101 determines that the mouse cursor 500 is detected on the area of the shooting button 403, the process proceeds from step S203 to step S204.

  If the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the process returns from step S203 to step S201.

  In step S <b> 204, the CPU 101 determines whether the mouse 106 a button of the operation unit 106 that operates the mouse cursor 500 has been clicked.

  When the CPU 101 determines that the button of the mouse 106a has been clicked, the process proceeds from step S204 to step S211.

  When the CPU 101 does not determine that the button of the mouse 106a has been clicked, the flowchart returns from step S204 to step S203.

  In step S <b> 211, when the mouse cursor 500 is over the shooting button 403 area by the CPU 101, when the mouse 106 a button is clicked, the CPU 101 causes the communication unit 104 to generate a shooting start command and add it to the transmission command queue 600. To do. In this flowchart, the process proceeds from step S211 to step S212.

  In step S <b> 212, the CPU 101 determines whether or not the mouse cursor 500 is hovered over the area of the shooting button 403.

  If the CPU 101 determines that the mouse cursor 500 has been detected on the area of the shooting button 403, the process proceeds from step S212 to step S213.

  When the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the flowchart returns from step S212 to step S212.

  In step S213, the CPU 101 determines whether or not the mouse 106a button of the operation unit 106 for operating the mouse cursor 500 has been clicked.

  When the CPU 101 determines that the button of the mouse 106a has been clicked, the process proceeds from step S213 to step S214.

  When the CPU 101 does not determine that the button of the mouse 106a has been clicked, the flowchart returns from step S213 to step S212.

  In step S214, if the mouse 101 is clicked on the area of the shooting button 403 by the CPU 101 and the mouse 106a is clicked, the CPU 101 causes the communication unit 104 to generate a shooting stop command and add it to the transmission command queue 600. To do. In this flowchart, the process proceeds from step S214 to step S206.

  After execution of step S214, when a command for stopping shooting in the transmission command queue 600 is transmitted to the digital camera 200, shooting processing is executed in step S115 of the flowchart of FIG. In step S106, image data transmission is executed, and the image data is sent to the PC 100.

  As described above, when the mouse cursor 500 is moved over the area of the shooting button 403 by operating the mouse 106a, the PC 100 instructs the digital camera 200 to perform shooting preparation processing. Thereafter, when the mouse cursor 500 is on the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to start shooting when the mouse 106a is clicked. Thereafter, when the mouse cursor 500 is on the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to stop shooting when the mouse 106a is clicked.

  In step S <b> 206, the CPU 101 displays the image data sent from the digital camera 200 on the display unit 105. Here, this flowchart ends.

  Thereby, the operation when the photographing mode is bulb photographing in the PC 100 can be realized.

  Further, in the second embodiment, in the flowchart of FIG. 14, the start of shooting is performed with the first click, and the stop of shooting is performed with the second click. However, step S212 and step S231 in the flowchart of FIG. 18 may be used. That is, the shooting stop may be performed after the first click when the mouse cursor disappears from the shooting button area or when the click is released while the mouse cursor is on the shooting button area.

  When a large number of shooting start commands and shooting stop commands are generated within a certain period of time, duplicate commands may be thinned out for a certain period of time. Alternatively, duplicate commands may be thinned out a certain number of times.

(Embodiment 3)
In the first and second embodiments, normal shooting and bulb shooting have been described. In the third embodiment, mirror-up shooting will be described.

<Mirror up shooting>
In mirror-up shooting, when the shutter button is pressed for the first time, a mirror-up operation is executed, and when the shutter button is pressed for the second time, a shooting operation is executed, and a series of shooting operations is completed.

  In the state of S1 of the first shutter button, the same shooting preparation processing as that in the state of S1 of normal shooting is performed, but in the state of S2 of the first shutter button, processing in the state of S2 of normal shooting Unlike the mirror up. Then, in the state of S2 of the first shutter button, a shooting operation is performed, and a series of shooting operations is completed.

  As an operation at the time of mirror-up shooting using the camera control screen 400, mirror-up is executed when the shooting button 403 is clicked for the first time, and shooting operation is executed when the button is clicked for the second time.

<Camera control screen 400>
Next, the description of the camera control screen 400, which is an example of the menu screen, will be described with reference to FIG.

  The shutter button 403 performs shooting processing in two states, S1 in which the shutter button is half-pressed and S2 in which the shutter button is fully pressed. When the mouse cursor 500 moves on the shutter button 403 and the operation mode of the digital camera 200 is the mirror-up shooting mode, the PC 100 instructs the digital camera 200 to start shooting preparation processing. When the mouse cursor 500 is clicked on the shutter button 403 and the operation mode of the digital camera 200 is the mirror up shooting mode, the PC 100 instructs the digital camera 200 to start the shooting process. After that, when the mouse cursor 500 is clicked with the shutter button 403 being on and the operation mode of the digital camera 200 is the mirror-up shooting mode, the PC 100 instructs the digital camera 200 to stop the shooting process. . Thereby, a series of photographing operations is completed.

<Operation of Digital Camera 200 upon Receiving Command 700 from PC 100>
Next, a description will be given with reference to FIG. 15 using a flowchart illustrating an example of processing performed by the digital camera 200 according to the third embodiment.

  In step S121, when the operation mode of the digital camera 200 is set to the mirror-up shooting mode by the operation unit 207, the CPU 201 causes the communication unit 204 to generate an operation mode signal indicating the shooting mode. Then, an instruction is sent to the communication unit 104 of the PC 100 via the USB cable 300. In this case, the flowchart proceeds from step S121 to step S102.

  In step S102, the CPU 201 determines whether or not the communication unit 204 has received a shooting preparation command. If the CPU 201 determines that a shooting preparation command has been received, the CPU 201 sets a shooting preparation flag in the memory 202. In this case, the flowchart proceeds from step S102 to step S103.

  If the CPU 201 determines that it has not received a shooting preparation command, the flowchart returns from step S102 to step S102.

  In step S <b> 103, the CPU 201 issues an instruction to cause the imaging unit 208 to execute shooting preparation processing.

  When the shooting preparation process is performed, the flowchart proceeds from step S103 to step S112.

  In step S <b> 112, the CPU 201 determines whether the communication unit 204 has received a shooting start command from the PC 100. In this case, the flowchart proceeds from step S112 to step S122.

  When the CPU 201 determines that the communication unit 204 has not received the shooting start command, the CPU 201 resets the shooting preparation flag in the memory 202. In this case, the flowchart returns from step S112 to step S102.

  In step S122, the CPU 201 instructs a mirror (not shown) to mirror up. In this case, the flowchart proceeds from step S122 to step S114.

  In step S <b> 114, the CPU 201 determines whether the communication unit 204 has received a shooting stop command from the PC 100. When the CPU 201 determines that the communication unit 204 has received a shooting stop command, the CPU 201 sets a shooting flag in the memory 202. In this case, the flowchart proceeds from step S114 to step S105.

  When the CPU 201 determines that the communication unit 204 has not received the shooting stop command, the flowchart returns from step S114 to step S114.

  In step S <b> 105, the CPU 201 issues an instruction to cause the imaging unit 208 to perform shooting processing.

  When the photographing process is performed, the CPU 201 resets the photographing preparation flag and the photographing flag in the memory 202. In this case, the flowchart proceeds from step S105 to step S106.

  In step S <b> 106, after the photographing process is completed, the CPU 201 causes the communication unit 204 to generate a preparation completion signal indicating that preparation for transmission of image data is completed, and instructs the PC 100 to transmit the preparation completion signal. After the preparation completion signal is transmitted to the PC 100, the CPU 201 reads the image data from the recording unit 203 and instructs the communication unit to transmit the read image data to the PC. In this case, the processing of the digital camera 200 performed in this flowchart ends.

<Operation of PC 100 when Sending Command 700 to Digital Camera 200>
Next, a description will be given with reference to FIG. 16 using a flowchart illustrating an example of processing performed by the PC 100 according to the third embodiment.

  In step S <b> 201, the CPU 101 determines whether or not the mouse cursor 500 is detected on the area of the shooting button 403. In this case, the flowchart proceeds from step S201 to step S202. When the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the flowchart returns from step S201 to step S201.

  In step S 202, when the CPU 101 detects the mouse cursor 500 on the area of the shooting button 403, the CPU 101 causes the communication unit 104 to generate a shooting preparation command and adds it to the transmission command queue 600. The processing of the transmission command queue 600 will be described later. In this case, the flowchart proceeds from step S202 to step S203.

  In step S203, it is determined whether or not the mouse cursor 500 is over the area where the mouse cursor 500 is over in step S201.

  When the CPU 101 determines that the mouse cursor 500 is detected on the area of the shooting button 403, the process proceeds from step S203 to step S204.

  If the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the process returns from step S203 to step S201.

  In step S <b> 204, the CPU 101 determines whether the mouse 106 a button of the operation unit 106 that operates the mouse cursor 500 has been clicked.

  When the CPU 101 determines that the button of the mouse 106a has been clicked, the process proceeds from step S204 to step S211.

  When the CPU 101 does not determine that the button of the mouse 106a has been clicked, the flowchart returns from step S204 to step S203.

  In step S <b> 211, when the mouse cursor 500 is over the shooting button 403 area by the CPU 101, when the mouse 106 a button is clicked, the CPU 101 causes the communication unit 104 to generate a shooting start command and add it to the transmission command queue 600. To do. In this flowchart, the process proceeds from step S211 to step S212.

  In step S <b> 212, the CPU 101 determines whether or not the mouse cursor 500 is hovered over the area of the shooting button 403.

  If the CPU 101 determines that the mouse cursor 500 has been detected on the area of the shooting button 403, the process proceeds from step S212 to step S213.

  When the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the flowchart returns from step S212 to step S212.

  In step S213, the CPU 101 determines whether or not the mouse 106a button of the operation unit 106 for operating the mouse cursor 500 has been clicked.

  When the CPU 101 determines that the button of the mouse 106a has been clicked, the process proceeds from step S213 to step S214.

  When the CPU 101 does not determine that the button of the mouse 106a has been clicked, the flowchart returns from step S213 to step S212.

  In step S214, if the mouse 101 is clicked on the area of the shooting button 403 by the CPU 101 and the mouse 106a is clicked, the CPU 101 causes the communication unit 104 to generate a shooting stop command and add it to the transmission command queue 600. To do. In this flowchart, the process proceeds from step S214 to step S206.

  After execution of step S214, when a command to stop shooting in the transmission command queue 600 is transmitted to the digital camera 200, shooting processing is executed in step S105 of the flowchart of FIG. In step S106, image data transmission is executed, and the image data is sent to the PC 100.

  As described above, when the mouse cursor 500 is moved over the area of the shooting button 403 by operating the mouse 106a, the PC 100 instructs the digital camera 200 to perform shooting preparation processing. Thereafter, when the mouse cursor 500 is on the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to start shooting when the mouse 106a is clicked. Thereafter, when the mouse cursor 500 is on the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to stop shooting when the mouse 106a is clicked.

  In step S <b> 206, the CPU 101 displays the image data sent from the digital camera 200 on the display unit 105. Here, this flowchart ends.

  Thereby, the operation when the shooting mode is mirror-up shooting in the PC 100 can be realized.

  In the third embodiment, in the flowchart of FIG. 16, the start of shooting is performed with the first click, and the stop of shooting is performed with the second click. However, step S212 and step S231 in the flowchart of FIG. 18 may be used. That is, the shooting stop may be performed after the first click when the mouse cursor disappears from the shooting button area or when the click is released while the mouse cursor is on the shooting button area.

  When a large number of shooting start commands and shooting stop commands are generated within a certain period of time, duplicate commands may be thinned out for a certain period of time. Alternatively, duplicate commands may be thinned out a certain number of times.

(Embodiment 4)
In Embodiments 1, 2, and 3, normal shooting, bulb shooting, and mirror-up shooting have been described. In Embodiment 4, continuous shooting will be described.

<Continuous shooting>
In continuous shooting, when the shutter button is pressed, a shooting operation is started, and a shooting operation equivalent to normal shooting is repeated one or more times. When the shutter button is released, the shooting operation is terminated and a series of shooting operations is completed.

  In the state of the shutter button S1, shooting preparation processing equivalent to that in the S1 state of normal shooting is performed, but shooting is started in the state of the shutter button S2 unlike the processing in the state of S2 of normal shooting. Only do. Then, when the shutter button is released, shooting is stopped and a series of shooting operations is completed.

  As an operation during continuous shooting using the camera control screen 400, shooting is started when the shooting button 403 is clicked. Then, the shooting is stopped when the mouse cursor 500 disappears on the area of the shooting button 403 or when the click is released in a state where it is on the area of the shooting button 403.

<Camera control screen 400>
Next, the description of the camera control screen 400, which is an example of the menu screen, will be described with reference to FIG.

  The shutter button 403 performs shooting processing in two states, S1 in which the shutter button is half-pressed and S2 in which the shutter button is fully pressed. When the mouse cursor 500 moves onto the shutter button 403 and the operation mode of the digital camera 200 is the continuous shooting mode, the PC 100 instructs the digital camera 200 to start shooting preparation processing. When the mouse cursor 500 is clicked on the shutter button 403 and the digital camera 200 is in the continuous shooting mode, the PC 100 instructs the digital camera 200 to start the shooting process. After that, when the mouse cursor 500 is not over the shooting button 403 area or when the click is released while the mouse cursor 500 is over the shooting button 403 area, the PC 100 instructs the digital camera 200 to stop the shooting process. To do. Thereby, a series of photographing operations is completed.

<Operation of Digital Camera 200 upon Receiving Command 700 from PC 100>
Next, with reference to FIG. 17, a description will be given using a flowchart showing an example of processing performed by the digital camera 200 according to the fourth embodiment.

  In step S131, when the operation mode of the digital camera 200 is set to the continuous shooting mode by the operation unit 207, the CPU 201 causes the communication unit 204 to generate an operation mode signal indicating the shooting mode. Then, an instruction is sent to the communication unit 104 of the PC 100 via the USB cable 300. In this case, the flowchart proceeds from step S131 to step S102.

  In step S102, the CPU 201 determines whether or not the communication unit 204 has received a shooting preparation command. If the CPU 201 determines that a shooting preparation command has been received, the CPU 201 sets a shooting preparation flag in the memory 202. In this case, the flowchart proceeds from step S102 to step S103.

  If the CPU 201 determines that it has not received a shooting preparation command, the flowchart returns from step S102 to step S102.

  In step S <b> 103, the CPU 201 issues an instruction to cause the imaging unit 208 to execute shooting preparation processing.

  When the shooting preparation process is performed, the flowchart proceeds from step S103 to step S112.

  In step S <b> 112, the CPU 201 determines whether the communication unit 204 has received a shooting start command from the PC 100. When the CPU 201 determines that the communication unit 204 has received a shooting start command, the CPU 201 sets a shooting flag in the memory 202. In this case, the flowchart proceeds from step S112 to step S113.

  When the CPU 201 determines that the communication unit 204 has not received the shooting start command, the CPU 201 resets the shooting preparation flag in the memory 202. In this case, the flowchart returns from step S112 to step S102.

  In step S <b> 113, the CPU 201 issues an instruction to cause the imaging unit 208 to start shooting processing. In the continuous shooting mode, the shooting process equivalent to the normal shooting is repeated once or more by starting the shooting process. In this case, the flowchart proceeds from step S113 to step S114.

  In step S <b> 114, the CPU 201 determines whether the communication unit 204 has received a shooting stop command from the PC 100. When the CPU 201 determines that the communication unit 204 has received a shooting stop command, the CPU 201 resets the shooting preparation flag and the shooting flag in the memory 202. In this case, the flowchart proceeds from step S114 to step S115.

  When the CPU 201 determines that the communication unit 204 has not received the shooting stop command, the flowchart returns from step S114 to step S114.

  In step S <b> 115, the CPU 201 issues an instruction to end the shooting process in the imaging unit 208. In this flowchart, the process proceeds from step S115 to step S106.

  In step S <b> 106, after the photographing process is completed, the CPU 201 causes the communication unit 204 to generate a preparation completion signal indicating that preparation for transmission of image data is completed, and instructs the PC 100 to transmit the preparation completion signal. After the preparation completion signal is transmitted to the PC 100, the CPU 201 reads the image data from the recording unit 203 and instructs the communication unit to transmit the read image data to the PC. In this case, the processing of the digital camera 200 performed in this flowchart ends.

<Operation of PC 100 when Sending Command 700 to Digital Camera 200>
Next, with reference to FIG. 18, a description will be given using a flowchart illustrating an example of processing performed by the PC 100 according to the fourth embodiment.

  In step S <b> 201, the CPU 101 determines whether or not the mouse cursor 500 is detected on the area of the shooting button 403. In this case, the flowchart proceeds from step S201 to step S202. When the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the flowchart returns from step S201 to step S201.

  In step S 202, when the CPU 101 detects the mouse cursor 500 on the area of the shooting button 403, the CPU 101 causes the communication unit 104 to generate a shooting preparation command and adds it to the transmission command queue 600. The processing of the transmission command queue 600 will be described later. In this case, the flowchart proceeds from step S202 to step S203.

  In step S203, it is determined whether or not the mouse cursor 500 is over the area where the mouse cursor 500 is over in step S201.

  When the CPU 101 determines that the mouse cursor 500 is detected on the area of the shooting button 403, the process proceeds from step S203 to step S204.

  If the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the process returns from step S203 to step S201.

  In step S <b> 204, the CPU 101 determines whether the mouse 106 a button of the operation unit 106 that operates the mouse cursor 500 has been clicked.

  When the CPU 101 determines that the button of the mouse 106a has been clicked, the process proceeds from step S204 to step S211.

  When the CPU 101 does not determine that the button of the mouse 106a has been clicked, the flowchart returns from step S204 to step S203.

  In step S <b> 211, when the mouse cursor 500 is over the shooting button 403 area by the CPU 101, when the mouse 106 a button is clicked, the CPU 101 causes the communication unit 104 to generate a shooting start command and add it to the transmission command queue 600. To do. In this flowchart, the process proceeds from step S211 to step S212.

  In step S <b> 212, the CPU 101 determines whether or not the mouse cursor 500 is hovered over the area of the shooting button 403.

  If the CPU 101 determines that the mouse cursor 500 has been detected on the area of the shooting button 403, the process proceeds from step S212 to step S231.

  When the CPU 101 does not detect the mouse cursor 500 on the area of the shooting button 403, the process proceeds from step S212 to step S214.

  In step S231, the CPU 101 determines whether or not the button of the mouse 106a of the operation unit 106 for operating the mouse cursor 500 has been released.

  If the CPU 101 determines that the button on the mouse 106a has been released, the process proceeds from step S231 to step S214.

  When the CPU 101 does not determine that the button on the mouse 106a has been released, the process returns from step S231 to step S212.

  In step S <b> 214, when the mouse 101 is over the shooting button 403 by the CPU 101 and the mouse 106 a button is released, the CPU 101 causes the communication unit 104 to generate a shooting stop command. Then, it is added to the transmission command queue 600. In this flowchart, the process proceeds from step S214 to step S206.

  After the execution of step S214, when a shooting stop command in the transmission command queue 600 is transmitted to the digital camera 200, shooting processing is executed in step S115 of the flowchart of FIG. In step S106, image data transmission is executed, and the image data is sent to the PC 100.

  As described above, when the mouse cursor 500 is moved over the area of the shooting button 403 by operating the mouse 106a, the PC 100 instructs the digital camera 200 to perform shooting preparation processing. Thereafter, when the mouse cursor 500 is on the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to start shooting when the mouse 106a is clicked. After that, when the mouse cursor 500 disappears from the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to stop shooting. Alternatively, when the mouse 106a is released when the mouse cursor 500 is over the area of the shooting button 403 where the mouse is over, the PC 100 instructs the digital camera 200 to stop shooting.

  In step S <b> 206, the CPU 101 displays the image data sent from the digital camera 200 on the display unit 105. Here, this flowchart ends.

  Thereby, the operation when the shooting mode is continuous shooting can be realized in the PC 100.

  Further, in the fourth embodiment, in the flowchart of FIG. 18, the shooting start is performed by clicking, and the shooting stop is performed when the mouse cursor disappears from the area of the shooting button. Alternatively, it is performed when the click is released while the mouse cursor is on the area of the shooting button. However, the shooting stop may be performed at the second click after the first click.

  When a large number of shooting start commands and shooting stop commands are generated within a certain period of time, duplicate commands may be thinned out for a certain period of time. Alternatively, duplicate commands may be thinned out a certain number of times.

  In addition, as a pointing device of Embodiments 1-4, the mouse | mouth was demonstrated as an example. However, a cursor that is a symbol indicating the current location on the screen, such as a track pad, a track ball, or a touch panel display, may be moved to designate an input position or coordinates on the screen.

(Other embodiments)
The above-described embodiment can also be realized in software by a computer of a system or apparatus (or CPU, MPU, etc.). Therefore, the computer program itself supplied to the computer in order to implement the above-described embodiment by the computer also realizes the present invention. That is, the computer program itself for realizing the functions of the above-described embodiments is also one aspect of the present invention.

  The computer program for realizing the above-described embodiment may be in any form as long as it can be read by a computer. For example, it can be composed of object code, a program executed by an interpreter, script data supplied to the OS, but is not limited thereto. A computer program for realizing the above-described embodiment is supplied to a computer via a storage medium or wired / wireless communication. Examples of the storage medium for supplying the program include a magnetic storage medium such as a flexible disk, a hard disk, and a magnetic tape, an optical / magneto-optical storage medium such as an MO, CD, and DVD, and a nonvolatile semiconductor memory.

  As a computer program supply method using wired / wireless communication, there is a method of using a server on a computer network. In this case, a data file (program file) that can be a computer program forming the present invention is stored in the server. The program file may be an executable format or a source code. The program file is supplied by downloading to a client computer that has accessed the server. In this case, the program file can be divided into a plurality of segment files, and the segment files can be distributed and arranged on different servers. That is, a server apparatus that provides a client computer with a program file for realizing the above-described embodiment is also one aspect of the present invention.

  In addition, a storage medium in which the computer program for realizing the above-described embodiment is encrypted and distributed is distributed, and key information for decrypting is supplied to a user who satisfies a predetermined condition, and the user's computer Installation may be allowed. The key information can be supplied by being downloaded from a homepage via the Internet, for example. Further, the computer program for realizing the above-described embodiment may use an OS function already running on the computer. Further, a part of the computer program for realizing the above-described embodiment may be configured by firmware such as an expansion board attached to the computer, or may be executed by a CPU provided in the expansion board. Good.

It is a figure which shows an example of the remote control system which concerns on Embodiment 1-4. It is a block diagram which shows an example of schematic structure of the remote control system which concerns on Embodiment 1 and 4. FIG. It is a figure which shows an example of the camera control screen 400 displayed on a control apparatus. 3 is a flowchart illustrating an example of processing performed by the imaging apparatus according to the first embodiment. 3 is a flowchart illustrating an example of processing performed by the control device according to the first embodiment. 6 is a diagram illustrating an example of a transmission command queue 600 according to Embodiments 1 to 4. FIG. 6 is a diagram illustrating an example of a command 700 according to Embodiments 1 to 4. FIG. 6 is a flowchart illustrating an example of a process for adding a command 700 performed by the control device according to the first to fourth embodiments. 6 is a flowchart illustrating an example of a command 700 extraction process performed by the control device according to the first to fourth embodiments. 6 is a flowchart illustrating an example of a process for adding a command 700 performed by the control device according to the first to fourth embodiments. 6 is a flowchart illustrating an example of a process for adding a command 700 performed by the control device according to the first to fourth embodiments. 6 is a flowchart illustrating an example of a process for adding a command 700 performed by the control device according to the first to fourth embodiments. 10 is a flowchart illustrating an example of processing performed by the imaging apparatus according to the second embodiment. 6 is a flowchart illustrating an example of processing performed by a control device according to the second embodiment. 10 is a flowchart illustrating an example of processing performed by the imaging apparatus according to the third embodiment. 10 is a flowchart illustrating an example of processing performed by the control device according to the third embodiment. 10 is a flowchart illustrating an example of processing performed by the imaging apparatus according to the fourth embodiment. 6 is a flowchart illustrating an example of processing performed by a control device according to a fourth embodiment.

Explanation of symbols

100 control device 101 CPU
102 memory 103 ROM
104 Communication Unit 105 Display Unit 106 Operation Unit 106a Mouse 106b Keyboard 200 Imaging Device 201 CPU
202 Memory 203 Recording Unit 204 Communication Unit 205 Image Processing Unit 206 Display Unit 207 Operation Unit 208 Imaging Unit 300 USB Cable 400 Camera Control Screen 401 View Area 402 Status Area 403 Shutter Button 404 Parameter Area 500 Mouse Cursor 600 Transmission Command Queue 700 Command 710 Send command 720 Registration time 730 Count

Claims (8)

A control method for remotely controlling an imaging device,
A management step for managing a command for causing the imaging apparatus to perform AF processing and a command for causing the imaging apparatus to perform shooting processing;
In the management step, if there is a duplicate command in the command for performing the AF process, the command is thinned out, and if there is a duplicate command in the command for performing the shooting process, the command is not thinned out. Characteristic control method. A display step of controlling to display an image transmitted from the imaging device on a camera control screen;
A generation step for generating a command for causing the imaging apparatus to perform AF processing when a predetermined area displayed on the camera control screen and a cursor operated using a pointing device overlap; The control method according to claim 1, further comprising:   In the generating step, when the pointing device is clicked in a state where a predetermined area displayed on the camera control screen and a cursor operated using the pointing device are overlapped, The control method according to claim 2, wherein a command for performing a photographing process is generated.   The control according to any one of claims 1 to 3, wherein, in the management step, if there are duplicate commands in the command for performing the AF process, the duplicate commands are thinned out for a predetermined time. Method.   4. The control according to claim 1, wherein, in the management step, when there are duplicate commands in the command for performing the AF process, the duplicate commands are thinned out a predetermined number of times. 5. Method.   The command for performing the shooting process is a command for controlling the start and end operations of shooting, a command for controlling the mirror-up operation and the shooting operation, and a start and end of continuous shooting. The control method according to claim 1, wherein the control method is at least one of the following commands. A program for causing a computer to execute a control method for remotely controlling an imaging apparatus,
The control method is:
A management step for managing a command for causing the imaging apparatus to perform AF processing and a command for causing the imaging apparatus to perform shooting processing;
In the management step, if there is a duplicate command in the command for performing the AF process, the command is thinned out, and if there is a duplicate command in the command for performing the shooting process, the command is not thinned out. A featured program. A computer-readable storage medium storing the program according to claim 7.

Images