JP4508721B2 - Mobile device and control method thereof - Google Patents

Description

  The present invention relates to a portable device and a control method thereof that can be applied to shorten the start-up time of a device such as an imaging device to which a storage medium can be attached and detached to reduce power consumption.

  Conventionally, there is a portable device in which a storage medium for storing information can be detachably attached. A digital camera will be described as an example of this type of portable device.

  FIG. 14 is a block diagram illustrating a configuration of a digital camera according to a conventional example.

  In FIG. 14, an RTC (Real Time Clock) 287 is a clock management device that manages the time in the sub CPU 201 and the digital camera, and is always supplied with power. The sub CPU 201 is composed of a CPU with low power consumption, and a RAM 205 used by the sub CPU 201 and a ROM 203 storing a program of the sub CPU 201 are connected. In addition, the sub CPU 201 indicates an attachment / detachment state of an operation system 209 such as a mode dial for instructing an operation mode of the digital camera and various buttons, and a storage medium 271 such as a compact flash (registered trademark) for storing captured images. The signal is connected. The sub CPU 201 always monitors signals indicating the operation state of the operation system 209 and the attachment / detachment state of the storage medium 271.

  The sub CPU 201 is connected to the power control unit 281 to control the power of the entire digital camera. The sub CPU 201 determines whether the power is on or off based on the operation state of the operation system 209, and passes through the power control unit 281. The power is turned on / off. The power supply control unit 281 is connected to the power supply 289, generates a voltage required for each part of the digital camera from the voltage of the power supply 289, and supplies power to each part. Also, ON / OFF control of the power supplied to each unit is performed by control from the sub CPU 201.

  A ROM 207 is connected to the main CPU 245, and a program for operating the main CPU 245 is stored in the ROM 207. When the main CPU 245 is activated, the program is read from the ROM 207 and activated. A RAM 217 is connected to the main CPU 245. The RAM 217 temporarily stores captured image data and temporarily stores data necessary for the operation of the main CPU 245. Memory.

  The main CPU 245 is connected to a lens driving unit 219, an imaging unit 221 including an image sensor and a timing generator, an image display unit 259 including an LCD, and a storage medium 271. The lens driving unit 219 to the storage medium 271 are configured to be controlled by the main CPU 245 and perform a target process. Then, the sub CPU 201 and the main CPU 245 are connected by communication means so that the state of each other can be detected. The main CPU 245 is configured to detect an operation state of the operation system 209 using this communication unit, determine a mode such as a shooting mode and a playback mode, and perform processing for each mode.

  Further, the main CPU 245 monitors the operation state of the operation system 209 and the attachment / detachment state of the storage medium 271 via the sub CPU 201. When the main CPU 245 is turned off by the operation system 209, when the storage medium 271 is attached, the main CPU 245 stores information such as the file system of the storage medium 271 in the ROM 207, When the process is completed, the sub CPU 201 is notified of the end of the power-off process.

  When the sub CPU 201 is notified of the end of the power OFF process from the main CPU 245, it stops the power supply of the system. The sub CPU 201 keeps a history of the operation state of the operation system 209 and the attachment / detachment state of the storage medium 271 even when the power is off. When the operation is turned on by the operation system 209, the sub CPU 201 turns on the power via the power control unit 281. Turn it on. As a result, power is supplied to the main CPU 245 to start up. When the storage medium 271 is not attached / detached in the power-off state, the main CPU 245 reads information such as the file system of the storage medium 271 saved in the ROM 207 and initializes the storage medium 271. We are trying to shorten it. Of course, when the storage medium 271 is attached or detached, the storage medium 271 is initialized.

On the other hand, a technique related to control by a sub CPU has been proposed in a device including a main CPU and a sub CPU as described above (for example, see Patent Document 1).
JP 2002-237777 A

  However, in the portable device having the first CPU (main CPU) that is constantly supplied with power as shown in the above-described conventional example and constantly monitoring the attachment / detachment state of the storage medium, the entire device In addition to the first CPU that manages the above, another second CPU (sub CPU) must be mounted. Therefore, there is a problem that the number of parts increases and the cost becomes high.

  In recent years, portable devices have been reduced in size, and the mounting area of devices that can be mounted on portable devices has also decreased. Therefore, in the downsized portable device, there is a problem that it is difficult to secure a mounting area for mounting the second CPU in addition to the first CPU.

  In recent years, power-saving CPUs with low power consumption have been developed. However, the power consumption required to drive the power-saving CPU is still higher than the power consumption of power-saving devices such as RTC. For this reason, in a portable device equipped with a power-saving CPU, if the power-saving CPU is always driven in a power-off state, there is a problem that the power consumption increases as compared with a device that does not always drive the CPU.

  However, if monitoring of the storage medium attachment / detachment state is stopped in the power-off state, the information on the storage medium must be acquired and initialized every time it is started up, so that the startup time becomes long. In general, as the capacity of the storage medium increases, the time spent for initialization becomes longer. However, since the capacity of the storage medium has increased remarkably in recent years, there is a problem that the startup time becomes longer year by year.

  An object of the present invention is to provide a portable device and a control method therefor that do not require mounting of a plurality of CPUs and that can shorten the startup time and power consumption.

In order to achieve the above-described object, a portable device according to the present invention is a portable device including a CPU that controls the entire device and a connection unit that can attach and detach a storage medium that stores information. Regardless, the monitoring circuit for monitoring the attachment / detachment state of the storage medium with respect to the connection means, the monitoring result storage means for storing the monitoring result based on the monitoring of the attachment / detachment state of the storage medium by the monitoring circuit, and the CPU when performing, before SL and a communication unit to the monitoring result stored accessible from the CPU to the monitoring result storage means, wherein the monitoring circuit, that the storage medium is detached from the connecting means After detecting this, monitoring of the attachment / detachment state of the storage medium is stopped .

In order to achieve the object described above, the control method of the present invention includes a CPU which controls the overall apparatus, a control method for a portable device that stores media with a connection means detachable for storing information, pre SL CPU Regardless of the operation state, a monitoring step for monitoring the attachment / detachment state of the storage medium with respect to the connection means and a monitoring result based on the monitoring of the attachment / detachment state of the storage medium by the monitoring step are stored in the monitoring result storage means. A monitoring result storage step , and a communication step for allowing the CPU to access the monitoring result stored in the monitoring result storage means by the communication means when the CPU performs a startup process , the monitoring step Then, after detecting that the storage medium is removed from the connection means, the monitoring circuit monitors the attachment / detachment state of the storage medium. Characterized in that it stop.

Further, according to the present invention, the monitoring circuit is input via the connection means when a signal input via the connection means reaches a predetermined level or when a switch attached to the connection means is operated. When the signal input via the connection means becomes a predetermined level when the media storage cover attached to the connection means is opened. It may be configured to detect the attachment / detachment of a medium.

Furthermore, the present invention may be configured to include power control means for controlling power to be supplied to the monitoring circuit and the monitoring result storage means even when the power of the portable device is off.

According to the present invention, regardless of the operation state of the CPU, the storage medium attachment / detachment state with respect to the connection means of the portable device is monitored, the monitoring result based on the monitoring of the storage medium attachment / detachment state is stored, and the CPU performs the startup process. the access from the CPU to the monitoring result stored in the monitoring result storage means when. Further, after detecting that the storage medium has been removed from the connection means, the monitoring circuit stops monitoring the state of attachment / detachment of the storage medium. Thereby, it is possible to monitor the attachment / detachment state of the storage medium with less power consumption. Moreover, it becomes unnecessary to mount a second CPU in the portable device in addition to the first CPU that manages the entire portable device as in the prior art, and the price can be reduced.

In addition, when the CPU performs a startup process, the storage media can be started without being initialized by reading the monitoring result of the storage medium attachment / detachment status from the monitoring result storage means via the communication means, thus shortening the startup time. can do.

Regardless of the operation state of the CPU , in other words, even when the portable device is in the power-off state, the monitoring circuit monitors the attachment / detachment state of the storage medium, so the attachment / detachment state of the storage medium can be monitored with low power consumption.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram showing a configuration of a digital camera as a portable device according to the first embodiment of the present invention.

  In FIG. 1, the digital camera includes a photographic lens 31, a shutter 33, an image sensor 35, a main CPU 45, an optical finder 69, a media detection circuit 85, and the like in each part of the camera body 29, so that the storage medium 71 can be attached and detached. It is configured.

  The taking lens 31 captures an optical image of a subject. The barrier 65 is a protection mechanism that prevents the imaging unit from being dirty or damaged by covering the imaging unit including the photographing lens 31. The shutter 33 has a diaphragm function. The image sensor 35 converts an optical image into an electrical signal. The A / D converter 37 converts the analog signal output from the image sensor 35 into a digital signal. The timing generation circuit 39 supplies a clock signal and a control signal to the image pickup device 35, the A / D converter 37, and the D / A converter 41, and is controlled by the memory control circuit 43 and the main CPU 45.

  The image processing circuit 47 performs predetermined pixel interpolation processing and color conversion processing on the image data output from the A / D converter 37 or the image data output from the memory control circuit 43, and the captured image data Is used to perform predetermined arithmetic processing. The main CPU 45 performs AF (autofocus) processing, AE (automatic exposure) processing, and EF (flash pre-flash) on the exposure control unit 49 and the distance measurement control unit 51 based on the calculation result obtained by the image processing circuit 47. Process. Further, the image processing circuit 47 also performs AWB (auto white balance) processing based on the result of predetermined calculation processing.

  The memory control circuit 43 controls the A / D converter 37, the timing generation circuit 39, the image processing circuit 47, the image display memory 53, the D / A converter 41, the memory 55, and the compression / decompression circuit 57, respectively. The image display memory 53 and the memory 55 are composed of the same RAM 17, but a predetermined area of the RAM 17 is an image display memory 53 and another predetermined area of the RAM 17 is a memory 55. The image data A / D converted by the A / D converter 37 is written into the image display memory 53 or the memory 55 via the image processing circuit 47 and the memory control circuit 43 or directly via the memory control circuit 43.

  The display image data written in the image display memory 53 is displayed by the image display unit 59 such as an LCD via the D / A converter 41. If the captured image data is sequentially displayed by the image display unit 59, an electronic viewfinder function can be realized. The image display unit 59 can arbitrarily turn on / off the display according to an instruction from the main CPU 45. When the display is turned off, the power consumption of the camera body 29 can be significantly reduced.

  The memory 55 is a memory for storing captured still images and moving images, and has a storage capacity sufficient to store a predetermined number of still images and moving images for a predetermined time. Thus, even in continuous shooting or panoramic shooting in which a plurality of still images are continuously shot, it is possible to write a large amount of image data to the memory 55 at high speed. The memory 55 can also be used as a work area for the main CPU 45. The compression / decompression circuit 57 is a circuit that compresses / decompresses image data, reads the image data stored in the memory 55, performs compression processing or decompression processing, and writes the processed image data to the memory 55.

  The exposure control unit 49 controls the shutter 33. The distance measurement control unit 51 controls the focusing of the photographic lens 31. The zoom control unit 61 controls zooming of the photographing lens 31. The barrier control unit 63 controls the operation of the barrier 65. The main CPU 45 controls the exposure control unit 49 and the distance measurement control unit 51 based on the result of calculating the captured image data by the image processing circuit 47.

  The main CPU 45 is a central processing unit that controls the digital camera. The main CPU 45 controls the power supplied from the power source 89 or the backup power source 83 to each unit via the power control unit 81, detects the operation key input in the operation unit 79, and the like. And the operation of each part of the digital camera is controlled based on the input of the operation key. Further, the main CPU 45 executes the processing shown in the flowchart of FIG. 9 based on the program stored in the ROM 7.

  The display unit 67 displays an operation state, a message, and the like of the digital camera using characters, images, sounds, and the like according to the execution of the program in the main CPU 45. The display unit 67 is installed at a single or a plurality of positions in the vicinity of the operation unit 79 of the camera body 29 so as to be easily visible, and is configured by a combination of, for example, an LCD, an LED, and a sounding element. In addition, the display unit 67 is partially installed in the optical viewfinder 69.

  Among the display contents of the display unit 67, what is displayed on the LCD or the like includes single shot / continuous shooting display, self-timer display, compression rate display, number of recorded pixels, number of recorded pixels, number of remaining images that can be captured, shutter Speed display, Aperture value display, Exposure compensation display, Flash display, Red-eye reduction display, Macro shooting display, Buzzer setting display, Clock battery level display, Battery level display, Error display, Multi-digit number information display, Memory There are an attachment / detachment state display of the media 71, a communication I / F operation display, a date / time display, and the like. Among the display contents of the display unit 67, those displayed in the optical viewfinder 69 include in-focus display, camera shake warning display, flash charge display, shutter speed display, aperture value display, exposure correction display, and the like.

  The mode dial switch 73, the shutter switches 75 and 77, and the operation unit 79 are for inputting various instructions to the camera main body 29. Consists of multiple combinations.

  The mode dial switch 73 can switch and set each function mode such as power-off, automatic shooting mode, shooting mode, panoramic shooting mode, playback mode, multi-screen playback / erase mode, and PC connection mode.

  The shutter switches SW1 and 75 are turned ON during the operation of a shutter button (not shown), and instruct to start operations such as AF processing, AE processing, AWB processing, and EF processing. The shutter switches SW2 and 77 are turned on when the operation of a shutter button (not shown) is completed, and an exposure process of writing a signal read from the image sensor 35 as image data in the memory 55 via the A / D converter 37 and the memory control circuit 43. , A development process using operations in the image processing circuit 47 and the memory control circuit 43, a recording process in which the image data is read from the memory 55, compressed by the compression / decompression circuit 57, and written to the storage medium 71. Instructs the start of processing operation.

  The operation unit 79 includes a menu button, a set button, a macro button, a multi-screen playback page break button, a flash setting button, a single shooting / continuous shooting / self-timer switching button, a menu movement + (plus) button, a menu movement − (minus). Buttons, a playback image move + (plus) button, a playback image-(minus) button, a shooting image quality selection button, an exposure correction button, a date / time setting button, and the like.

  The power control unit 81 includes a battery detection circuit, a DC-DC converter, a switch circuit that switches a block to be energized, and the like, and supplies a necessary voltage to each unit for a necessary period based on the control of the main CPU 45. In FIG. 1, only lines for supplying power to the main CPU 45, the media detection circuit 85, and the RTC 87 are shown, but of course, power is also supplied to other units.

  The backup power supply 83 is composed of a coin battery, a supercomputer, or the like, and supplies power to the media detection circuit 85 and the RTC 87 that must always be supplied when no power is supplied from the power supply 89 via the power supply control unit 81. Supply. When the backup power supply 83 is a secondary battery, the backup power supply 83 may be charged when the power supply from the power supply 89 is supplied. The connectors 91 and 93 connect the camera body 29 and the power source 89. The power source 89 includes a primary battery such as an alkaline battery or a lithium battery, a secondary battery such as a NiCd battery, a NiMH battery, or a Li battery, an AC adapter, or the like.

  The interface 96 manages an interface with a storage medium 71 such as a memory card or a hard disk. The connector 97 connects the camera body 29 and the storage medium 71. In the present embodiment, the camera main body 29 is configured to include one interface and connector for attaching the storage medium 71, but of course, the interface and connector for attaching the storage medium may include any number of single or plural systems. It does not matter as a configuration. Moreover, it is good also as a structure provided with combining the interface and connector of a different standard. The interface and connector may be configured using a PCMCIA (Personal Computer Memory Card International Association) card, a CF (Compact Flash (registered trademark)) card, or the like.

  The optical viewfinder 69 can perform photographing using only the optical viewfinder 69 without using the electronic viewfinder function of the image display unit 59. The optical viewfinder 69 can perform some functions of the display unit 67, for example, focus display, camera shake warning display, flash charge display, shutter speed display, aperture value display, exposure correction display, and the like.

  An RTC (Real Time Clock) 87 is time management means for managing the time in the digital camera, and the power is always supplied from the power supply 89 or the backup power supply 83 via the power supply control unit 81 even when the camera body 29 is turned off. It is configured to be supplied. The main CPU 45 can read the time from the RTC 87 via serial communication. The RTC 87 is connected to a clock oscillator 13 that outputs a clock for operating the RTC 87. The RTC 87 performs time management based on the clock of the clock oscillator 13. The main CPU 45 is connected to a clock oscillator 11 that outputs a relatively high frequency clock. The clock output from the clock oscillator 13 is set to a frequency lower than that of the clock output from the clock oscillator 11.

  A media detection signal indicating whether the storage medium 71 is attached to or detached from the connector 97 is connected (input) to the media detection circuit 85 via the connector 97. The media detection circuit 85 detects the attachment / detachment state of the storage medium 71 based on the media detection signal regardless of the operation state of the main CPU 45. The media detection signal is also connected (input) to the main CPU 45. As with the RTC 87, the media detection circuit 85 is configured such that power is always supplied from the power control unit 81 even when the camera body 29 is in a power-off state. By accessing the media detection circuit 85 from the main CPU 45 via serial communication, it is possible to recognize the attachment / detachment state of the storage media 71.

  In FIG. 1, a block surrounded by a line 9 indicates an operation system, a block surrounded by a line 17 indicates a RAM, and a block surrounded by a line 19 indicates an imaging unit (the photographic lens 31). , Shutter 33 and barrier 65), and a block surrounded by a line 21 indicates a signal processing system of the image pickup unit (image pickup device 35).

  Next, the connection (input) form of the media detection signal to the media detection circuit 85 of the digital camera will be described with reference to FIGS.

  As shown in FIG. 2, when a storage medium 71 is attached to a connector (not shown) of the digital camera, the media detection signal connected to the media detection circuit 85 is at a low level.

  In addition, as shown in FIG. 3, when the storage medium 71 is attached to a connector (not shown) of the digital camera, the media detection signal connected to the media detection circuit 85 may be at a high level.

  Further, as shown in FIG. 4, when a switch 98 is provided in the connector 97 of the digital camera and the storage medium 71 is attached to the connector 97, the switch 98 pressed by the storage medium 71 is activated. The media detection signal connected to the media detection circuit 85 may be at a low level.

  Further, as shown in FIG. 5, when a switch 98 is provided in the connector 97 of the digital camera and the storage medium 71 is attached to the connector 97, the switch 98 pressed by the storage medium 71 is activated. The media detection signal connected to the media detection circuit 85 may be at a high level.

  4 and 5, the switch 98 is not normally in mechanical contact with the storage medium 71, and when the storage medium 71 is attached to the connector 97, the switch 98 is in mechanical contact with the storage medium 71. The structure is as follows. On the other hand, the switch 98 may normally be mechanically in contact with the storage medium 71, and when the storage medium 71 is attached to the connector 97, the switch 98 may not be mechanically in contact with the storage medium 71.

  In addition, as shown in FIG. 6, a media storage lid 70 for storing the storage media 71 is disposed in a connector (not shown) of the digital camera, and when the media storage lid 70 is opened, the level is set to the Low level or the High level. The lid detection signal may be connected to the media detection circuit 85 as a media detection signal.

  Next, the configuration of the media detection circuit 85 in the case where the connection (input) form of the media detection signal is shown in FIG. 2 will be described with reference to FIG.

  FIG. 7 is a block diagram showing the configuration of the media detection circuit 85.

  7, the media detection circuit 85 includes a switch 99, a switch 107, a buffer 103, a controller 108, a controller 109, a clock supply source 111, a timer 113, a register 115, a register 116, a bus interface 117, and an internal bus 119. .

  When the storage medium 71 is attached to the connector 97, a media detection signal indicating that the storage medium 71 is attached is input to the media detection circuit 85. The media detection signal becomes Low level when the storage medium 71 is attached to the connector 97, indicating that the storage medium 71 is attached. A resistor 101 is connected to the signal line to which the media detection signal is supplied, and the pull-up can be turned on / off under the control of the switch 99. In addition, a resistor 105 is connected to a signal line to which a media detection signal is supplied, and the pull-down can be turned on / off under the control of the switch 107.

  The media detection signal is input to the controller 108 via the buffer 103. The media detection signal is input to the buffer 103 via a chattering removal circuit (not shown) for removing chattering that occurs when the storage medium 71 is attached to the connector 97, and then input to the controller 108. It does not matter if it is configured. The switch 99 and the switch 107 are controlled by the controller 108, but both are not turned on at the same time and are not turned off at the same time, so that either one is turned on and the other is turned off. .

  The controller 108 is a storage medium detection controller that controls the switch 99 and the switch 107 in accordance with a control signal from the controller 109, detects the attachment / detachment state of the storage medium 71, and passes the signal to the controller 109. The controller 109 controls the entire medium detection circuit 85, outputs a control signal for causing the controller 108 to detect the attachment / detachment state of the storage medium 71, and outputs a signal indicating the detection result of the attachment / detachment state of the storage medium 71 from the controller 108. The attachment / detachment state detection result is stored in the register 115. Further, the controller 109 executes processing shown in the flowcharts of FIGS. 10 to 13 based on the program.

  The timer 113 measures the timing for the controller 109 to output a control signal that causes the controller 108 to detect the attachment / detachment state of the storage medium 71. The timer 113 is controlled to start / stop the measurement operation by a signal from the controller 109.

  The register 115 stores the detection result of the attachment / detachment state of the storage medium 71 described above. The register 115 is configured to be accessible from an external device such as the main CPU 45 via the bus interface 117. Thereby, an external device such as the main CPU 45 can recognize the attachment / detachment state of the storage medium 71 by reading the register 115. Further, the main CPU 45 performs activation processing based on the attachment / detachment state detection result stored in the register 115.

  The register 116 stores settings for the entire media detection circuit 85. The controller 109 controls the media detection circuit 85 according to the settings stored in the register 116. The register 116 is configured to be readable / writable from an external device such as the main CPU 45 via the bus interface 117. Thereby, the media detection circuit 85 can be controlled from an external device such as the main CPU 45.

  The clock supply source 111 supplies a clock for operating the media detection circuit 85. The clock supply source 111 may be arranged outside the media detection circuit 85 instead of inside. The timer 113 operates based on the clock supplied from the clock supply source 111. The internal bus 119 connects the timer 113, the register 115, the register 116 and the bus interface 117 within the media detection circuit 85.

  As described above, according to the present embodiment, the digital camera includes the main CPU 45 that controls the digital camera, the media detection circuit 85 including the controller 109, the register 115, and the bus interface 117, and the RTC 87 that performs time management. And a connector 97 to / from which the storage medium 71 is attached / detached. The media detection circuit 85 monitors the attachment / detachment state of the storage medium 71 with respect to the connector 97 regardless of the operation state of the main CPU 45, and stores the attachment / detachment state detection result of the storage medium 71 in the register 115. When the main CPU 45 performs the startup process, the attachment / detachment state detection result in the register 115 can be accessed from the main CPU 45 via the bus interface 117.

  This eliminates the need to install a second CPU in the digital camera in addition to the first CPU (main CPU) that manages the entire digital camera as in the prior art, and the media detection circuit 85 including a controller and a register Since the second CPU can be configured at a lower cost than mounting in a digital camera, the price can be reduced.

  Further, when the main CPU 45 is activated, the result of detecting the attachment / detachment state of the storage medium 71 is read from the register 115 via the bus interface 117, so that the storage medium 71 can be activated without being initialized, thereby shortening the activation time. be able to.

  Regardless of the operation state of the main CPU 45, in other words, even when the camera body 29 is in a power-off state, the attachment / detachment state of the storage medium 71 is monitored by the media detection circuit 85 to which power is supplied via the power control unit 81. Therefore, the storage medium attachment / detachment state can be monitored with low power consumption.

[Second Embodiment]
The second embodiment of the present invention is different from the first embodiment described above in that the RTC 87 and the media detection circuit 85 are integrated into a single device. Since the other elements of the present embodiment are the same as the corresponding ones of the first embodiment (FIG. 1) described above, description thereof is omitted.

  First, before describing the configuration of the RTC 87 and the media detection circuit 85 as one device, the configuration of the RTC 87 will be described with reference to FIG.

  FIG. 8 is a block diagram showing the configuration of the RTC 87.

  8, the RTC 87 includes a controller 121, a timer 123, a register 125, a bus interface 127, an internal bus 129, and a clock supply unit 131.

  A clock serving as a reference signal for operating the RTC 87 is input to the clock supply unit 131 from the clock oscillator 13 outside the RTC 87. The clock supply unit 131 has a built-in PLL (Phase Lock Loop) and is configured to be able to multiply the input clock, and the clock necessary for the operation of the controller 121, timer 123, register 125, and bus interface 127. Supply. The controller 121 governs overall control of the RTC 87 and determines overall control of the RTC 87 based on setting values stored in the register 125.

  The timer 123 has a function of measuring a predetermined time or an arbitrary time and generating an interrupt, and a function of measuring hours, minutes, and seconds and storing the measured values in the register 125. The register 125 stores the setting value of the operation of the RTC 87 and the measured value of hours / minutes / seconds, and is configured to be accessible from an external device such as the main CPU 45 via the bus interface 127. Thereby, an external device such as the main CPU 45 can perform time recognition and control of the RTC 87.

  Comparing the media detection circuit 85 of FIG. 7 and the RTC 87 of FIG. 8, the media detection circuit 85 includes a controller, a timer, a register, and a bus interface as components, similar to the RTC 87. Therefore, the controller 121 of the RTC 87 is incorporated in the controller 109 of the media detection circuit 85, the register 125 of the RTC 87 is incorporated in the register 116 of the media detection circuit 85, and the timer 123 of the RTC 87 is incorporated in the timer 113 of the media detection circuit 85. To do. As a result, the RTC 87 can be incorporated into the media detection circuit 85, and the RTC 87 and the media detection circuit 85 can be configured by one device.

  As described above, according to the present embodiment, by configuring the RTC 87 and the media detection circuit 85 as one device, the controller, the register, the timer, and the like can be shared, so that the number of components and the mounting area are not increased. In addition, the RTC function and the storage media detection function can be mounted on the digital camera. Further, since the main CPU 45 does not need to separately access the RTC 87 and the media detection circuit 85, the control can be simplified.

[Third Embodiment]
The third embodiment of the present invention differs from the first and second embodiments described above in that the main CPU 45 operates as shown in FIG. Since the other elements of the present embodiment are the same as the corresponding ones of the first embodiment (FIG. 1) described above, description thereof is omitted.

  FIG. 9 is a flowchart showing the operation of the main CPU 45.

  In FIG. 9, the main CPU 45 determines whether or not the power ON indicating the activation of the digital camera is detected (step S101). If the power ON is detected, the process proceeds to step S102, and if the power ON is not detected, Wait until power ON is detected. When the main CPU 45 detects that the power is turned on, the main CPU 45 performs an initial setting for enabling the main CPU 45 to operate (step S102), and then communicates with the medium detection circuit 85 to indicate the result of detecting the attachment / detachment state of the storage medium 71. A media detection flag as a flag is read from the register 115 of the media detection circuit 85 (step S103).

  In the power-on state, the main CPU 45 can monitor the attachment / detachment state of the storage medium 71 and there is no need to operate the media detection circuit 85, so the main CPU 45 stops the operation of the media detection circuit 85 (step S104). . Next, the main CPU 45 determines whether or not the storage medium 71 has been removed from the connector 97 from the media detection flag read in step S103 (step S105). If it is determined that the storage medium 71 has not been removed from the connector 97, the process proceeds to step S106. If it is determined that the storage medium 71 has been removed from the connector 97, the process proceeds to step S107.

  When the storage medium 71 is removed from the connector 97, the main CPU 45 initializes the storage medium 71, reads the file management information from the initialized storage medium 71 and stores it in the ROM 7 (step S107), and then proceeds to step S108. Transition. On the other hand, when the storage medium 71 is not removed from the connector 97, the previous file management information of the storage medium 71 is stored in the ROM 7, so the main CPU 45 reads the previous file management information of the storage medium 71 from the ROM 7. After (step S106), the process proceeds to step S108.

  Next, the main CPU 45 performs a normal camera operation according to the user's operation (step S108). Description of the camera operation is omitted because it is not directly related to this process. Next, the main CPU 45 determines whether or not a power OFF is detected (step S109). When the power OFF is detected, the main CPU 45 activates the media detection circuit 85 and performs a power OFF process (step S110). If the power ON is detected, the camera operation is continued, and the process proceeds to step S108.

  To summarize the above control, when the main CPU 45 performs the startup process, if it is determined from the contents of the media detection flag that the storage medium 71 has not been removed from the connector 97, the file management information stored in the ROM 7 is read out. If it is determined that the storage medium 71 has been removed from the connector 97, the file management information is read from the storage medium 71 and the activation process is performed.

  As described above, according to the present embodiment, when the storage medium 71 is not removed from the connector 97, the file management information stored in the ROM 7 having a higher access speed than the storage medium 71 is used. It is not necessary to read out the file management information from the storage medium 71 every time it is activated, and the activation time can be shortened.

[Fourth Embodiment]
In the fourth embodiment of the present invention, as shown in FIG. 10, the media detection circuit 85 does not always monitor the attachment / detachment state of the storage medium 71 as compared with the first to third embodiments described above. However, it is different in that monitoring is performed again after a predetermined waiting time. Since the other elements of the present embodiment are the same as the corresponding ones of the first embodiment (FIG. 1) described above, description thereof is omitted.

  FIG. 10 is a flowchart showing the operation of the media detection circuit 85.

  In FIG. 10, the timer 113 of the media detection circuit 85 generates an interrupt every predetermined time (for example, 0.1 msec). First, the controller 109 waits for an interrupt notifying that the time for monitoring the attachment / detachment state of the storage medium 71 has elapsed from the timer 113 (step S201). When an interrupt from the timer 113 occurs, the controller 109 temporarily stops the timer 113, turns on the switch 99, and turns off the switch 107 (step S202).

  Next, the controller 109 monitors a media detection signal output from the buffer 103 and indicating whether the storage medium 71 is attached to the connector 97 (step S203). If the media detection signal is at the low level, it indicates that the storage medium 71 is attached to the connector 97, and if the media detection signal is at the power supply level, it indicates that the storage medium 71 is not attached to the connector 97. Yes.

  Next, the controller 109 stores the monitoring result (attachment / detachment state detection result) of the storage medium 71 acquired in the monitoring in step S203 in the register 115 (step S204). Thereafter, the controller 109 resumes the operation of the timer 113 that has been stopped, turns off the switch 99, turns on the switch 107 (step S205), and proceeds to step S201.

  As described above, according to the present embodiment, since the media detection circuit 85 monitors the attachment / detachment state of the storage medium 71 every predetermined time, compared to the case where the attachment / detachment state of the storage medium 71 is constantly monitored. Power consumption can be reduced.

[Fifth Embodiment]
In the fifth embodiment of the present invention, the time at which the timer 113 of the media detection circuit 85 generates an interrupt can be set to an arbitrary time, as shown in FIG. 11, in contrast to the fourth embodiment described above. The register 116 is different in that a set time area for storing a set time for the timer 113 to generate an interrupt is provided. Since the other elements of the present embodiment are the same as the corresponding ones of the first embodiment (FIG. 1) described above, description thereof is omitted.

  FIG. 11 is a flowchart showing the operation of the media detection circuit 85.

  In FIG. 11, the timer 113 of the media detection circuit 85 generates an interrupt every set time stored in the set time area of the register 116. First, the controller 109 waits for an interrupt notifying that the time for monitoring the attachment / detachment state of the storage medium 71 has elapsed from the timer 113 (step S301). When an interrupt from the timer 113 occurs, the controller 109 temporarily stops the timer 113, turns on the switch 99, and turns off the switch 107 (step S302).

  Next, the controller 109 monitors a media detection signal output from the buffer 103 and indicating whether the storage medium 71 is attached to the connector 97 (step S303). Next, the controller 109 stores the monitoring result (attachment / detachment state detection result) of the storage medium 71 acquired in the monitoring in step S303 in the register 115 (step S304). Next, the controller 109 reads the set time to be set in the timer 113 from the register 116 (step S305), and sets the set time in the timer 113 (step S306). Thereafter, the controller 109 resumes the operation of the timer 113 that has been stopped, turns off the switch 99, turns on the switch 107 (step S307), and proceeds to step S301.

  The main CPU 45 can set the interrupt generation time of the timer 113 to an arbitrary time by accessing the register 116 via the bus interface 117 of the media detection circuit 85. The time for monitoring the attachment / detachment state can be arbitrarily set according to the situation. For example, when the voltage of the power supply 89 is low when the main CPU 45 stops, it is assumed that the time for the media detection circuit 85 to monitor the attachment / detachment state of the storage medium 71 is extended in order to make the power supply 89 last longer. Is done.

  As described above, according to the present embodiment, the monitoring time for the media detection circuit 85 to monitor the attachment / detachment state of the storage medium 71 can be set from the main CPU 45, so that the voltage of the power supply 89 decreases. Since the monitoring time can be appropriately changed according to the situation, the power consumption can be further reduced as compared with the fourth embodiment.

[Sixth Embodiment]
In the sixth embodiment of the present invention, the main CPU 45 does not set the monitoring time for the media detection circuit 85 to monitor the attachment / detachment state of the storage medium 71 in the fifth embodiment described above. The difference is that the attachment / detachment history of attachment / detachment (insertion / removal) of the media 71 is stored in the register 116 and the controller 109 determines the monitoring time based on the attachment / detachment history of the register 116. Since the other elements of the present embodiment are the same as the corresponding ones of the first embodiment (FIG. 1) described above, description thereof is omitted.

  FIG. 12 is a flowchart showing the operation of the media detection circuit 85.

  In FIG. 12, the timer 113 of the media detection circuit 85 generates an interrupt every time set in the register 116. First, the controller 109 waits for an interrupt notifying that the time for monitoring the attachment / detachment state of the storage medium 71 has elapsed from the timer 113 (step S401). When an interrupt from the timer 113 occurs, the controller 109 temporarily stops the timer 113, turns on the switch 99, and turns off the switch 107 (step S402).

  Next, the controller 109 monitors a media detection signal output from the buffer 103 and indicating whether the storage medium 71 is attached to the connector 97 (step S403). Next, the controller 109 stores the monitoring result (attachment / detachment state detection result) of the storage medium 71 acquired in the monitoring of step S303 in the register 115 and stores the monitoring result as the attachment / detachment history in the attachment / detachment history area of the register 116 ( Step S404). Next, the controller 109 reads the attachment / detachment history from the attachment / detachment history area of the register 116 (step S405), performs statistical calculation such as an average value and a histogram of the time interval when the storage medium 71 is attached / detached from the attachment / detachment history. The optimum value of the time interval for monitoring the attachment / detachment of 71 is calculated (step S406).

  Next, the controller 109 sets the optimum value of the time interval for monitoring the attachment / detachment of the calculated storage medium 71 in the timer 113 (step S407). Thereafter, the controller 109 resumes the operation of the timer 113 that has been stopped, turns off the switch 99, turns on the switch 107 (step S307), and proceeds to step S301.

  As described above, according to the present embodiment, since the time for monitoring the attachment / detachment state of the storage medium 71 is determined based on the attachment / detachment history of the attachment / detachment of the storage medium 71, the attachment / detachment of the storage medium 71 is frequently performed. When it is not performed, the number of times of monitoring the attachment / detachment of the storage medium 71 is reduced. As a result, the power consumption can be further reduced as compared with the fourth embodiment.

[Seventh Embodiment]
In the seventh embodiment of the present invention, when the media detection circuit 85 detects once that the storage medium 71 has been removed from the connector 97, the memory is stored in the first to sixth embodiments described above. The difference is that monitoring of the attachment / detachment state of the media 71 is stopped. Since the other elements of the present embodiment are the same as the corresponding ones of the first embodiment (FIG. 1) described above, description thereof is omitted.

  FIG. 13 is a flowchart showing the operation of the media detection circuit 85.

  In FIG. 13, the controller 109 of the media detection circuit 85 reads an operation flag for operating or stopping the media detection circuit 85 provided in the register 115, and determines the state of the operation flag (step S501). . If the operation flag indicates stop, the process returns to step S501. On the other hand, when the operation flag indicates an operation, the controller 109 stores an attachment / detachment monitoring result (insertion / removal monitoring result), which is a result of monitoring the attachment / detachment state of the storage medium 71, in the register 115 (step S502).

  Next, the controller 109 determines the attachment / detachment monitoring result (insertion / removal monitoring result) (step S503). If it is determined that the storage medium 71 has not been removed from the connector 97, the process proceeds to step S502. On the other hand, if it is determined that the storage medium 71 has been removed from the connector 97, the controller 109 sets the operation flag to a state indicating stop (step S504), and proceeds to step S501.

  As described above, according to the present embodiment, after the storage medium 71 is once removed from the connector 97, monitoring of the storage medium attachment / detachment state by the medium detection circuit 85 is stopped, so that power consumption is further reduced. be able to.

[Other embodiments]
In the first to seventh embodiments, the digital camera has been described as an example of the portable device. However, the present invention is not limited to this, and the present invention is also applicable to other portable devices having a configuration in which a storage medium can be attached and detached. be able to.

  In the first embodiment, the media detection circuit 85 has a configuration in which the register 115 that stores the attachment / detachment state detection result of the storage medium 71 and the register 116 that stores the entire setting of the media detection circuit 85 are provided separately. . As a modification of this, it is possible to provide an area for storing the attachment / detachment state detection result and an area for storing the entire setting of the media detection circuit 85 in one register.

  In the fourth embodiment, the medium detection circuit 85 monitors the attachment / detachment state of the storage medium 71 with a predetermined waiting time. As a modification of this, there are provided a plurality of stages of power saving modes respectively associated with a plurality of waiting times for monitoring the attachment / detachment state of the storage medium 71, and the user is provided with a plurality of stages of power saving modes displayed on the display unit 67 etc. When a desired power saving mode is selected from among them, the storage medium 71 may be monitored with a waiting time corresponding to the selected power saving mode.

  In the fifth embodiment, the time at which the timer 113 of the media detection circuit 85 generates an interrupt can be set to an arbitrary time, and the set time is stored in the register 116. As a modification of this, there are provided a plurality of stages of power saving modes respectively associated with a plurality of set times when the timer 113 generates an interrupt, and the user can select from among the plurality of stages of power saving modes displayed on the display unit 67 or the like. When a desired power saving mode is selected, a setting time corresponding to the selected power saving mode may be stored in the register 116.

  The present invention supplies a software program (flowcharts in FIGS. 9 to 13) for realizing the functions of the above-described embodiments to a computer or CPU, and the computer or CPU reads and executes the supplied program. Can be achieved.

  In this case, the program is directly supplied from a storage medium storing the program, or downloaded from another computer or database (not shown) connected to the Internet, a commercial network, a local area network, or the like. Supplied.

  The form of the program may be in the form of object code, program code executed by an interpreter, script data supplied to an OS (operating system), and the like.

  The present invention also supplies a computer or CPU with a storage medium storing a software program that implements the functions of the above-described embodiments, and the computer or CPU reads and executes the program stored in the storage medium. Can also be achieved.

  In this case, the program code itself read from the storage medium realizes the functions of the above-described embodiments, and the storage medium storing the program code constitutes the present invention.

  As a storage medium for storing the program code, for example, ROM, RAM, NV-RAM, floppy (registered trademark) disk, hard disk, optical disk (registered trademark), magneto-optical disk, CD-ROM, MO, CD-R, CD -RW, DVD-ROM, DVD-RAM, DVD-RW, DVD + RW, magnetic tape, nonvolatile memory card, etc.

  The function of the above-described embodiment is not only by executing the program code read from the computer, but the OS or the like running on the computer performs part or all of the actual processing based on the instruction of the program code. Can also be realized.

It is a block diagram which shows the structure of the digital camera as a portable apparatus which concerns on the 1st Embodiment of this invention. It is the schematic which shows the structural example of a storage medium and a media detection circuit. It is the schematic which shows the structural example of a storage medium and a media detection circuit. It is the schematic which shows the structural example of a storage medium and a media detection circuit. It is the schematic which shows the structural example of a storage medium and a media detection circuit. It is the schematic which shows the structural example of the media storage cover and media detection circuit of a connector. It is a block diagram which shows the structure of a media detection circuit. It is a block diagram which shows the structure of RTC which concerns on the 2nd Embodiment of this invention. It is a flowchart which shows operation | movement of the main CPU which concerns on the 3rd Embodiment of this invention. It is a flowchart which shows operation | movement of the media detection circuit based on the 4th Embodiment of this invention. It is a flowchart which shows operation | movement of the media detection circuit based on the 5th Embodiment of this invention. It is a flowchart which shows operation | movement of the media detection circuit based on the 6th Embodiment of this invention. It is a flowchart which shows operation | movement of the media detection circuit based on the 7th Embodiment of this invention. It is a block diagram which shows the structure of the digital camera which concerns on a prior art example.

Explanation of symbols

7 ROM (corresponding to management information storage means)
29 Camera body (compatible with mobile devices and imaging devices)
45 Main CPU (corresponding to CPU )
71 Storage media 85 Media detection circuit (supports monitoring circuit )
87 RTC (corresponding to time management means)
97 Connector (corresponding to connection method)
109 Controller (supports monitoring circuit )
115, 116 registers (corresponding to monitoring result storage means)
117 Bus interface (corresponding to communication means)

Claims (8)

In a portable device provided with a CPU for controlling the entire device and a connecting means to which a storage medium for storing information is detachable,
A monitoring circuit for monitoring the attachment / detachment state of the storage medium with respect to the connection means regardless of the operation state of the CPU;
Monitoring result storage means for storing a monitoring result based on monitoring of the attachment / detachment state of the storage medium by the monitoring circuit;
A communication unit that enables the CPU to access the monitoring result stored in the monitoring result storage unit when the CPU performs a startup process;
The portable circuit according to claim 1, wherein the monitoring circuit stops monitoring the attachment / detachment state of the storage medium after detecting that the storage medium is removed from the connection means. A time management means for managing the time in the portable device;
2. The portable device according to claim 1, wherein the monitoring circuit, the monitoring result storage unit, and the time management unit are configured as one device. Management information storage means for storing file management information of the storage medium,
When the CPU performs the startup process, if it is determined from the monitoring result stored in the monitoring result storage means that the storage medium is not removed from the connection means, the CPU stores the management information in the management information storage means. The file management information is read and the activation process is performed. When it is determined that the storage medium is removed from the connection means, the file management information is read from the storage medium and the activation process is performed. The portable device according to claim 1 or 2.   The portable device according to any one of claims 1 to 3, wherein the monitoring circuit monitors the attachment / detachment state of the storage medium every predetermined time. The time monitoring circuit monitors the detachment state of the storage medium, the portable device according to any one of claims 1 to 4, characterized in that from the CPU can be set via the communication means.   The time for the monitoring circuit to monitor the attachment / detachment state of the storage medium is determined based on the monitoring result stored in the monitoring result storage means. The portable device as described in.   The portable device according to claim 1, wherein the portable device is an imaging device including a digital camera. In a control method of a portable device provided with a CPU for controlling the entire device and a connection means to which a storage medium for storing information is detachable,
A monitoring step of monitoring, by a monitoring circuit, whether or not the storage medium is attached to or detached from the connection means regardless of the operation state of the CPU;
A monitoring result storage step of storing in the monitoring result storage means a monitoring result based on the monitoring of the attachment / detachment state of the storage medium by the monitoring step;
A communication step of enabling the CPU to access the monitoring result stored in the monitoring result storage means by the communication means when the CPU performs a startup process;
In the monitoring step, after detecting that the storage medium has been removed from the connection means, monitoring of the attachment / detachment state of the storage medium by the monitoring circuit is stopped.

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