JP2011112736A - Imaging system, body unit, lens unit and method for evaluating remaining capacity of battery in lens interchangeable type imaging system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens interchangeable type imaging system capable of accurately determining propriety of an operation mode to respective operation modes of an entire imaging system, by lessening a number of possessed data to the utmost. <P>SOLUTION: A body unit 2 includes a power supply, an image display means for displaying a through-image or a reproduced image, and a basic data storage means for storing basic load information corresponding to independent operation of the body unit. Lens units 3 and 3' have a photographic optical system, an imaging means for photoelectrically converting a subject image, and a specific data storage means for storing a plurality of pieces of specific load information in accordance with the operation of the lens units 3 and 3'. The body unit 2 and the lens units 3 and 3' can communicate with each other, and the body unit 2 acquires threshold information required to determine a state of the power supply by calculating a difference between the basic load information and the specific load information, and determines the propriety of the operation in each operation mode based on the threshold information and the state of the power supply actually detected. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an imaging system including a lens unit and a body unit that can be attached to and detached from the lens unit. More specifically, the power supply state can be determined according to the operation mode to determine whether the operation is possible. The present invention relates to a method for evaluating a remaining battery level of an imaging system, a body unit, a lens unit, and a lens-interchangeable imaging system.

2. Description of the Related Art Conventionally, an interchangeable lens type imaging system including a lens unit and a body unit that can be attached to and detached from the lens unit is known (see, for example, Patent Document 1).
In this conventional imaging system, the lens unit is provided with the lens unit for the purpose of providing the body unit with appropriate load information as the power state of each replaceable lens unit without any user effort or expense. A storage unit that stores load information corresponding to the operation, and a control unit that acquires load information corresponding to the operation of the lens unit instructed from the body unit from the storage unit and transmits the load information to the camera body via the communication unit. I have.

By the way, as load information, a lens unit having an image sensor and a lens unit having no image sensor have different power consumption and different control methods.
In addition, for example, the driving power consumption varies greatly depending on the operation specifications (focal length) of the lens unit and the differences in the imaging elements (CCD and CMOS, their sizes, the number of effective pixels, and the frame rate).
In the conventional interchangeable lens imaging system, only motor-driven load information is considered, and the load includes the difference in power consumption due to the difference in the imaging element including the size of the imaging element and the frame rate at the time of driving. It is not designed to provide information.

  Therefore, for example, when a lens unit having an image sensor different from the image sensor is attached to the body unit, as in the conventional case, the same fixed information is stored in the body unit. When the additional information is calculated using the same fixed information, the battery display related to the image sensor and the lens unit does not perform an operation corresponding to the load or the operation mode, and a normal display or end operation is performed. It is not performed and it is difficult for the user to use.

Therefore, it is conceivable that the load information for each lens unit is stored in the storage means (battery table) only on the body unit side. However, when the number of detachable lens units is increased, the load information for each lens unit is increased in advance in the storage means. Therefore, there is a limit to securing the data area. The same applies when load information is stored only on the lens unit side.
Furthermore, for each operation mode of the entire imaging system, if it is attempted to accurately determine whether or not the operation mode is appropriate for each operation mode using load information, a larger amount of data is required.

  An object of the present invention is to solve the above-mentioned problems. By distinguishing load information into basic load information on the body unit side and specific load information on the lens unit side, the amount of data to be held is reduced as much as possible. The present invention provides an interchangeable lens imaging system, a body unit, a lens unit, and a method for evaluating a remaining battery level of an interchangeable lens imaging system that can accurately determine whether or not the operation mode is appropriate for each operation mode of the entire imaging system. Objective.

The interchangeable lens imaging system according to claim 1 is an interchangeable lens imaging system including a lens unit and a body unit to which the lens unit can be attached and detached.
The body unit is a basic data for storing a plurality of basic load information corresponding to a power source, an image display means for displaying a through image or a reproduced image, a single operation of the body unit, and an operation when the lens unit is mounted. Storage means and communication means for communicating with the lens unit;
The lens unit communicates with the body unit, a photographing optical system, an imaging unit that photoelectrically converts a subject image, a specific data storage unit that stores a plurality of specific load information according to the operation of the lens unit, and the body unit. Communication means,
When any lens unit is mounted on the body unit, the body unit acquires the inherent load information stored in the inherent data storage means via the both communication means, and corresponds to the operation mode. The threshold information necessary to determine the power supply state is calculated from the basic load information and the specific load information to be operated, and whether or not the operation of the operation mode is possible based on the threshold information and the actually detected power supply state Is determined.

The interchangeable lens imaging system according to claim 2, wherein when the arbitrary lens unit is attached to the body unit, the image display unit includes the operation in addition to the through image or the reproduced image. A determination result of the power supply state according to the mode operation is displayed.
The interchangeable-lens imaging system according to claim 3 is characterized in that the basic load information and the specific load information are A / D conversion values related to the voltage of the power supply.
5. The interchangeable lens imaging system according to claim 4, wherein the basic load information and the specific load information are stored as natural numbers including 0, and an A / D conversion value of the basic load information is used to calculate an A of the specific load information. The value obtained by subtracting the / D conversion value corresponds to the A / D conversion value of the threshold information corresponding to the operation in the operation mode.

6. The interchangeable lens imaging system according to claim 5, wherein the basic load information of the body unit corresponds to at least information corresponding to a still image reproduction mode for reproducing and displaying a recorded image and a monitoring mode for displaying a through image. Information corresponding to a still image recording mode for shooting a still image, and information corresponding to a moving image recording mode for shooting a movie,
The unique load information of the lens unit includes at least information corresponding to the monitoring mode, information corresponding to the still image recording mode, and information corresponding to the moving image recording mode.
The interchangeable-lens imaging system according to claim 6 is characterized in that the basic data storage means has basic load information corresponding to the type of the power source.

The interchangeable lens imaging system according to claim 7 is an interchangeable lens imaging system including a lens unit and a body unit to which the lens unit can be attached and detached.
The body unit communicates with a power source, image display means for displaying a through image or a reproduced image, basic data storage means for storing basic load information corresponding to a single operation of the body unit, and the lens unit. Communication means,
The lens unit communicates with the body unit, an imaging optical system, an imaging unit that photoelectrically converts a subject image, a specific data storage unit that stores a plurality of specific load information according to the operation of the lens unit, and the body unit. Means,
In the body unit, calculation means for obtaining threshold information necessary for determining the state of the power source by performing a difference calculation between the basic load information and the specific load information, and actually detecting the threshold information. And determining means for determining whether or not the operation is possible for each operation mode based on the state of the power supply.

The interchangeable lens imaging system according to claim 8 is characterized in that the single operation is a still image reproduction mode, and the basic load information is load information of the still image reproduction mode.
The interchangeable lens imaging system according to claim 9 is characterized in that the specific load information is differential load information between the basic load information and the threshold information.

The interchangeable lens type imaging system according to claim 10 is characterized in that the differential load information is set for each operation mode of the camera.
12. The interchangeable lens type imaging system according to claim 11, wherein the operation mode of the lens unit is at least differential load information corresponding to a monitoring mode for displaying a through image, and a difference corresponding to a still image recording mode for capturing a still image. Load information and differential load information corresponding to a moving image recording mode for shooting a moving image.

The interchangeable lens type imaging system according to claim 12, wherein when the arbitrary lens unit is attached to the body unit, the image display unit includes, in addition to the through image or the reproduced image, The determination result of the state of the power supply according to the operation in the operation mode is displayed.
The interchangeable lens imaging system according to claim 13 is characterized in that the basic load information, the specific load information, and the threshold information are A / D conversion values related to the voltage of the power supply.

  15. The interchangeable lens imaging system according to claim 14, wherein an imaging-related unit other than the lens unit is detachable from the body unit, and the imaging-related unit includes information on the still image reproduction mode and the threshold information. Is recorded on the projector unit that projects the image recorded on the body unit, the high-capacity recording medium unit that can record and reproduce image data, or the body unit. It is a wireless unit or a sensing device that transmits the image data being transmitted.

According to a fifteenth aspect of the present invention, the body unit includes an imaging optical system, an imaging unit that photoelectrically converts a subject image, and a specific data storage unit that stores a plurality of specific load information corresponding to the operation mode, and at least one of the operation modes. Different types of lens units can be attached and detached,
A power source, an image display means for displaying a through image or a reproduction image, a basic data storage means for storing basic load information corresponding to a still image reproduction mode, a communication means for communicating with the lens unit, and the basic load. Imaging based on the threshold information necessary for determining the power supply state by performing a difference calculation between the information and the specific load information, and the threshold information and the actually detected power supply state Judgment means for judging whether the operation is possible or not is provided for each operation mode of the entire system.

In the body unit according to claim 16, when an arbitrary lens unit is mounted, the image display unit includes the power supply according to the operation in the operation mode in addition to the through image or the reproduction image. A state determination result is displayed.
The lens unit according to claim 17 includes a power source, image display means for displaying a through image or a reproduced image, basic data storage means for storing basic load information corresponding to a still image reproduction mode, and the basic load information. Calculation means for acquiring threshold information necessary to determine the power supply state based on the threshold value information and the actually detected power supply state for each operation mode of the entire imaging system. It can be attached to and detached from the body unit provided with a judging means for judging whether or not
An imaging optical system; an imaging unit that photoelectrically converts a subject image; a unique data storage unit that stores a plurality of specific load information according to operation; and a communication unit that communicates with the body unit; The load information is differential load information between the threshold information and the basic load information necessary for determining the state of the power source.

  The lens unit according to claim 18, wherein in the unique data storage means, differential load information corresponding to at least a monitoring mode for displaying a through image, differential load information corresponding to a still image recording mode for capturing a still image, Difference load information corresponding to a moving image recording mode for shooting a moving image is stored.

The battery remaining capacity evaluation method for an interchangeable lens imaging system according to claim 19 includes: a power source; image display means for displaying a through image or a reproduced image; and basic load information corresponding to a single operation of the body unit. A body unit having basic data storage means for storing, and communication means for communicating with the lens unit;
A lens having an imaging optical system, imaging means for photoelectrically converting a subject image, unique data storage means for storing a plurality of unique load information corresponding to the operation of the lens unit, and communication means for communicating with the body unit Unit,
A method for evaluating the remaining battery level used in an interchangeable lens imaging system comprising:
Threshold information necessary to determine the state of the power supply by performing a difference calculation between the basic load information and the specific load information is obtained, and based on the threshold information and the actually detected power supply state Whether or not the operation is possible is determined for each operation mode.

    The battery remaining capacity evaluation method for an interchangeable lens imaging system according to claim 20, wherein the single operation is a still image playback mode, and the basic load information is load information of the still image playback mode, The differential load information corresponding to the monitoring mode in which the operation mode of the lens unit at least displays a through image, the differential load information corresponding to the still image recording mode for capturing a still image, and the difference corresponding to the moving image recording mode for capturing a movie Load information.

  According to the present invention, the threshold information necessary for determining the state of the power supply for each operation mode as the entire imaging system can be obtained regardless of the operation specifications of the lens unit attached to and detached from the body unit. Distinguish between basic load information required to determine the state and specific load information that differs depending on the lens unit operation specifications. Only the basic load information is stored in the body unit, and only the specific load information is stored in the lens unit. When the entire imaging system is stored, threshold information necessary to determine the state of the power supply for the entire imaging system is calculated from the corresponding basic load information and the corresponding inherent load information according to the operation mode. Based on the threshold information obtained by this calculation and the information on the actually detected power supply state, Since in determining the can by a minimized amount of data to be held in the data storage means of the body unit and the lens unit, without any problem the determination of whether the operation of the entire imaging system.

1A and 1B are perspective views showing an example of an interchangeable lens type imaging system according to the present invention, in which FIG. 1A is a perspective view of a body unit to which a lens unit of a single focus lens is attached and detached, and FIG. It is a perspective view which shows the state which attaches the lens unit with a zoom function to the same body unit as the body unit shown to (a). FIG. 2 is a functional block diagram of the lens unit of the single focus lens shown in FIG. FIG. 3 is a functional block diagram of the body unit shown in FIGS. 1 (a) and 1 (b). FIG. 4 is a functional block diagram of the lens unit with an optical zoom function shown in FIG. FIG. 5 is an explanatory diagram of a functional block diagram of still another lens unit, and is a functional block diagram of a large image sensor. FIG. 6 is a matrix diagram showing an example of the relationship between the lens unit that can be attached to and detached from the body unit and the body unit, and FIG. 6A shows the remaining battery level corresponding to the state of END (zero remaining amount) as the power state. The threshold information for mark display shows a matrix of the operation mode and body unit of each lens unit. FIG. 6B shows the threshold information for battery remaining mark display corresponding to the state of NEND (nearly zero remaining). FIG. 6C shows a matrix of the operation mode and body unit of each lens unit, and FIG. 6C shows the operation mode and body of each lens unit regarding threshold information for battery remaining mark display corresponding to the state of HALF (half remaining amount). A matrix with units is shown. FIG. 7 shows the basic load information stored in the basic data storage means of the body unit, the specific load information stored in the specific data storage means of the lens unit, and the remaining battery level mark of the entire system for each operation mode of the entire imaging system. FIG. 7A is an explanatory diagram specifically showing an example of a relationship with display threshold information, and FIG. 7A is an explanatory diagram corresponding to a state of END (zero remaining amount) as a power supply state, and FIG. Is an explanatory diagram corresponding to the state of NEND (nearly zero remaining), and FIG. 7C is an explanatory diagram corresponding to the state of HALF (half remaining amount). FIG. 8 is a flowchart showing an example of a battery check as a power supply state according to the present invention. FIG. 9 is a diagram showing an example of a battery remaining amount display mark as a power state. FIG. 9A shows a case where the battery is fully charged, and FIG. 9B shows that the battery remaining amount is half. FIG. 9C shows a state where the remaining battery level is near zero, and FIG. 9D shows a state where there is no remaining battery level. FIG. 10 shows the basic load information stored in the basic data storage means of the body unit, the specific load information stored in the specific data storage means of the lens unit, and the remaining battery level of the entire system for each operation mode of the entire imaging system. FIG. 10A is an explanatory diagram specifically showing another example of the relationship with the mark display threshold information, and FIG. 10A is an explanatory diagram corresponding to the state of END (zero remaining amount) as the state of the power supply; FIG. 10B is an explanatory diagram corresponding to a state of NEND (nearly zero remaining amount), and FIG. 10C is an explanatory diagram corresponding to a state of HALF (half remaining amount). FIG. 11 is a perspective view showing a projector unit as an imaging-related device that can be attached to and detached from the body unit according to the present invention. FIG. 12 is a perspective view showing a hard disk unit as an imaging-related device that can be attached to and detached from the body unit according to the present invention. FIG. 13 is a perspective view showing a wireless unit as an imaging-related device that can be attached to and detached from the body unit according to the present invention. FIG. 14 is a perspective view showing a printer unit or a scanner unit as an imaging-related device that can be attached to and detached from the body unit according to the present invention.

(Overview of interchangeable lens imaging system)
FIG. 1 is a perspective view showing an example of an interchangeable lens type imaging system 1 according to the present invention. The imaging system 1 includes, for example, a body unit 2 and a lens unit 3 that can be attached to and detached from the body unit 2. 3 '. For example, the lens unit 3 is a type having a single focus lens, and the lens unit 3 ′ is a type with an optical zoom function.

  The lens units 3 and 3 ′ are detachably mounted on the mounting portion 2 </ b> A of the body unit 2. The body unit 2 is provided with a connector part 4 as communication means, and the lens units 3 and 3 'are provided with a connector part 5 as communication means.

Here, a lens unit 3 of a single focus lens and a lens unit 3 ′ with an optical zoom function are illustrated as lens units attached to the body unit 2, but these lens units 3, 3 are illustrated. The body unit 2 is detachable from a lens unit having a large image sensor and an imaging related unit described later.
For details of the detailed structures of the lens units 3 and 3 'and the body unit 2, refer to Japanese Patent Application No. 2009-252578 (filing date: November 4, 2009) if necessary.

(Explanation of functional block diagram of lens units 3, 3 'and body unit 2)
Next, a functional block diagram of the imaging system according to the present invention will be described with reference to FIGS. FIG. 2 is a functional block diagram of the lens unit 1 of the single focus lens according to the present invention, and FIG. 3 is a functional block diagram of the body unit 2 according to the present invention.

  In FIG. 2, a lens unit section 100 showing functional blocks of the lens unit 3 converts a lens group 101 as a photographing optical system including a focus lens and a subject image received through the lens group 101 from an optical signal to an electrical signal. An image pickup device (image pickup means) 102 that performs photoelectric conversion and outputs, an AFE (analog front end) 103 that converts a signal (analog image data) output from the image pickup device 102 into digital image data and performs signal amplification, and conversion The CPU 104 is a so-called image engine that performs predetermined image processing such as conversion processing to YUV data, JPEG compression processing, and RAW data generation processing on the digital image data that has been processed.

  The lens unit 100 also transmits a joint connector (connector unit 5) 105 constituting an inter-unit interface electrically connected to the body unit 2 and image data to the body unit 2 via the joint connector 105. The bidirectional bus 106, the control signal 107, the serial interface signal 108, and the SDIO signal 109 are respectively transmitted and received.

  In addition, the lens unit section 100 includes a motor driver 111 that controls a motor 110 used for extending and storing the lens barrel of the lens group 101. The motor driver 111 is controlled by a control signal 107 received from the body unit 2. With this mechanism, depending on the type of interchangeable lens, various operation controls such as housing the lens barrel when the power of the imaging system 1 is turned off, and performing a zooming operation by pressing a button (not shown) can be performed. .

  In addition, the lens unit 100 detects the power 112 supplied from the body unit 2 and the DC-DC converter 113 that generates various kinds of power necessary for the operation of the lens unit 100 from the power 112 supplied from the body unit 2. A sub-microcomputer (sub CPU) 114 that controls the DC-DC converter 113 and a detection circuit 115 that detects a teleconverter lens and a wide converter lens that can be mounted outside the lens unit 100 are provided.

  The lens unit 100 also includes a gyro sensor 116 that detects the tilt of the imaging system 1, an acceleration sensor 117 that detects acceleration applied to the imaging system 1, the tilt detected by the gyro sensor 116, and the acceleration detected by the acceleration sensor 117. Thus, a coil 118 for driving the lens group 101 and a Hall element 119 for detecting the driving amount of the coil 118 are provided. The gyro sensor 116, the acceleration sensor 117, the coil 118, and the hall element 119 can exhibit a camera shake prevention function.

  Further, the lens unit unit 100 stores software for performing image processing and operation control processing in a flash ROM 120, and uses a RAM (DDR-SDRAM) 121, which is a work area, for processing by this software. The CPU 104 is configured to control the operation and processing of each mechanism. Here, the flash ROM 120 functions as unique data storage means for storing unique load information described later.

  In FIG. 3, a body unit portion 200 showing functional blocks of the body unit 2 includes a joint connector (connector portion 4) 201 constituting an inter-unit interface that is electrically connected to the lens unit portion 100, and the joint connector 201. A bidirectional bus 203 for transferring image data received from the lens unit 100 to the CPU 202, conversion processing to YUV data for the image data received via the bidirectional bus 203, compression processing in JPEG format, JPEG format A CPU 202 (main CPU) as a so-called image engine that appropriately performs development processing from the image data, RAW data generation processing, the control signal 204 line connected to the control signal 107 line of the lens unit unit 100, and the lens unit unit 100. Serial interface It comprises a line of the serial interface signal 205 that connects to the line of over scan signals 108, and a line of SDIO signal 206 to connect the line of the SDIO signal 109 of the lens unit portion 100.

  The body unit 200 also selects a focus and release switch 207, which is a switch for starting the photographing operation of the imaging system 1 by a predetermined pressing operation, and the operation mode of the imaging system 1 set in the body unit 200. A switch 208 composed of a cross key or the like used for setting, and an input of the switch 208 is detected to perform a predetermined setting process and the power supplied from the lithium ion battery 209 is supplied using the DC-DC converter 210. A sub-microcomputer (sub CPU) 213 that controls the power source and controls the power switch 212 that is a switch for supplying power to the lens unit 100, and a power source voltage (power state) V of the lithium ion 209 (FIG. 8). Battery check circuit 209 ′ for checking) To have.

  Here, the lithium ion battery 209 and the DC-DC converter 210 constitute a power source. Information regarding the power state of the battery check circuit 209 ′ is A / D converted and input to the CPU 202. The CPU 202 constantly monitors the power supply voltage V based on the input information of the battery check circuit 209 '. The CPU 202 compares the power supply voltage V as threshold information described later, and is used, for example, for displaying the remaining battery level.

  The body unit 200 also includes a flash ROM 214 in which software for performing image processing and operation control processing is stored. Processing by this software is performed by a CPU 202 using a RAM (DDR-SDRAM) 215 that is a work area. Is configured to control the operation and processing of each mechanism. Here, the flash ROM 214 functions as basic data storage means for storing basic load information described later.

  The body unit 200 also includes an audio codec 216, a microphone 217 that inputs an audio signal to the audio codec 216, a speaker 218 that outputs sound from the audio codec 216, a USB interface connector 219, and an AV output connector 220. The HDMI signal output interface 221, the SD card memory 222, which is a detachable storage means for storing captured image files, and the strobe 223 that also serves as a connection circuit when an external strobe is attached to the body unit 200. And an LCD 224 and an EVF 225 that are image display means for monitoring and displaying the subject image during the focusing operation by operating the focus and release switch 207 and displaying the captured image data when performing the photographing operation. There. That is, the LCD 224 or the EVF 225 functions as an image display unit that displays a through image at the time of monitoring or a reproduction image obtained by reproducing a captured image.

FIG. 4 is a functional block diagram of another example of the lens unit section 100 (a lens unit 3 ′ equipped with an optical zoom).
In the lens unit portion 100 shown in FIG. 4, the lens group 101 has a zoom function, and a zoom motor 122 for moving the lens group 101 is provided. The focus lens and zoom lens provided in the lens group 101 can be operated in a predetermined manner by operating a zoom switch (not shown) provided in the body unit 200. Other configurations are the same as those of the lens unit 100 shown in FIG.

  FIG. 5 is a circuit block diagram showing still another example of the lens unit section 100. In the lens unit section 100 shown in FIG. 5, the configuration corresponding to the hall element 119, the coil 118, and the gyro sensor 116 (see FIG. 2) that perform the camera shake prevention operation is saved by making the imaging element 102 large. It is. Other configurations are the same as those of the lens unit 100 shown in FIG.

  In this way, various lens units 3 can be attached to and detached from the body unit 2, and with the lens unit 3 attached to the body unit 2, functions equivalent to those of the related art as a whole for each operation specification of the lens unit 3. An imaging system 1 is constructed. Hereinafter, an example of a combination of a lens unit and a body unit having different operation specifications will be described with reference to FIG.

(Description of an example of the combination of the operation mode of each lens unit and the body unit)
FIG. 6 is a matrix diagram showing the relationship between the lens unit that can be attached to and detached from the body unit and the body unit.
Here, the battery remaining amount display corresponds to four states of HUL (full), HALF (half remaining amount), NEND (near remaining amount zero), and END (zero remaining amount). Three threshold information HAV, NEV, and ENV (see FIG. 8) are necessary for the CPU 202 to determine the four power supply states. FIG. 6 shows the operation mode of each lens unit and the threshold information. A combination with a body unit is shown.

Here, as an operation mode of the entire imaging system, monitoring for displaying a through image, focus as a still image recording mode for shooting a still image, zoom for zooming, moving image recording for shooting a movie, mode A, mode B is assumed. The lens units have different operation modes depending on their specifications.
For example, the lens unit (LENZ1) 3 is of a single focus lens type, and this LENZ1 has operation modes of a monitoring operation, a focus operation, a moving image recording operation, and a mode A.

Further, for example, the lens unit (LENZ2) 3 ′ is of a type with an optical zoom function, and this LENZ2 is capable of operating modes of a monitoring operation, a focus operation, a zoom operation, a moving image recording operation, and a mode A. Have.
Further, for example, the lens unit (LENZ3) 3 is of a type having a large image sensor 102, and this LENZ3 has operation modes of a monitoring operation, a focus operation, a moving image recording operation, and a mode B.

  Here, the operation mode A and the operation mode B are for distinguishing the size of the image sensor 102. For example, the presence or absence of a camera shake correction mechanism is identified by the operation mode A and the operation mode B. The circles in each frame in FIGS. 6A to 6C indicate that the operation mode is present, and the blank means that the operation mode is not included.

  In this way, the operation mode differs depending on the specification of the lens unit.For example, even in a single-focus lens type lens unit with the same operation mode, there are those in which the detailed specifications differ depending on the operation mode. Although 100 types of lens units are shown, the present invention is not limited to this.

Since the power consumption during operation varies depending on each operation mode, it is necessary to set a threshold value for each operation mode. In particular, in the case of motor driving, moving image shooting, etc., the power consumption of the lens unit increases. Therefore, if load information regarding the power supply state for each operation mode with different specifications is prepared for each lens unit, and this load information is stored only in the storage means (battery table) on the body unit side, the removable lens unit When the number of devices increases, it is necessary to secure an extra data area, such as securing a large memory area in advance, and load information for each operation mode is stored on the lens unit side. The same applies to the case.
Furthermore, if it is attempted to accurately determine whether or not an operation mode is appropriate for each operation mode for each operation mode of the entire imaging system, a larger amount of data is required.

  Therefore, the load information necessary to determine the power supply state for each operation of the entire imaging system is used to determine the power supply state on the body unit side regardless of the operation specifications of the lens unit attached to and detached from the body unit. The basic load information required for the lens unit and the specific load information that differs depending on the operation specifications on the lens unit side are distinguished. Only the basic load information is stored in the body unit, and only the specific load information is stored in the lens unit. I will decide.

  In this embodiment, the body unit 2 is provided with load information relating to only a still image reproduction mode for reproducing and displaying a recorded image as a single operation in a memory table as basic load information. This memory table is prepared in the flash ROM 214 functioning as basic data storage means.

  Each lens unit stores a memory table corresponding to a specific operation mode of the lens unit as specific load information. The memory table is prepared in the flash ROM 120 that functions as a unique data storage means.

For each operation mode, threshold information necessary for determining the state of the power supply by combining the basic load information and the specific load information is obtained. Here, the CPU 202 is necessary to determine the state of the power supply according to the operation mode by calculating the basic load information only for the still image reproduction mode and the specific load information determined for each operation mode. It functions as a calculation means for acquiring threshold information to be used.
The CPU 202 functions as a determination unit that determines whether the operation in the operation mode is possible based on the threshold information and the actually detected power supply voltage V.

(Detailed description of examples of basic load information and specific load information)
The imaging system in which the body unit 2 and the lens unit 3 are integrated will be described. As an operation mode of the imaging system, a still image reproduction mode in which the image display means (LCD 224 and EVF 225) of the body unit 2 is operated, and the lens unit 3 is operated. There are a monitoring mode for driving, a focus mode for driving the focus lens, and a moving image recording mode for recording moving images.

  Next, an imaging system in which the body unit 2 and the lens unit 3 ′ are integrated will be described. As an operation mode of the imaging system, a still image reproduction mode in which image display means (LCD 224 and EVF 225) of the body unit 2 are operated, a lens There are a monitoring mode for operating the unit 3, a focus mode for driving a focus lens, a zoom mode for driving a zoom lens, and a moving image recording mode for recording a moving image.

  As described above, when the lens unit 3 attached to the body unit 2 is removed and a lens unit 3 ′ having a different specification from the lens unit 3 is attached to the body unit 2, the body unit 2 and the lens unit 3 ′ are The integrated imaging system 1 is different from the operation mode when the lens unit 3 is attached to the body unit 2.

  In this embodiment, the load information on the body unit side is information for only the still image reproduction mode, and the load information in this still image reproduction mode is stored and saved in the flash ROM 214 as basic load information. On the lens unit side, the differential load information is stored and saved in the flash ROM 120 as specific load information according to each operation mode.

The basic load information and the specific load information will be described in more detail using the explanatory diagram of the differential load information shown in FIG.
A flash ROM (basic data storage means) 214 of the body unit 2 stores an A / D conversion value (hereinafter referred to as an AD value) as basic load information in the still image reproduction mode.
Here, the AD value of the body unit 2 is set to “300”, “400”, and “500” corresponding to each threshold value information of ENV, NEV, and HAV (see FIG. 8). For convenience of explanation, the numerical values in the frame of FIG. 7 are displayed in decimal numbers.
Here, the AD value of the power supply voltage as threshold information is the AD value of the battery voltage. This AD value is stored as a natural number including zero.
On the other hand, the flash ROM 120 (unique data storage means) of the lens units 3 and 3 ′ stores an AD value as unique load information corresponding to this operation mode for each operation mode.
The AD value corresponds to the power supply voltage, and the battery voltage AD value is set to a smaller number in this embodiment as the power consumption increases. For example, an AD value “300” means a battery voltage of 3.7 V and a current consumption of 300 mA (power consumption 1.11 W), and an AD value “200” means a voltage of 3.7 V and a current consumption of 500 mA (power consumption 1.85 W). means.

  When the lens unit having a different specification is attached to the body unit 2, the load information of the still image reproduction mode as the basic load information of the body unit 2 is differentiated from the threshold information required for each operation mode as the entire imaging system, If this differential load information is used as specific load information required for each operation mode of a lens unit having different specifications, a storage area (memory table) required for each operation mode in the body unit 2 and each lens unit. ) Can be reduced.

  Here, the AD value stored in the unique data storage means of the lens unit 3 is “10” when the operation mode is monitoring and the battery level is zero (END), and the battery level is near zero (NEND). ) Is “5”, the battery level is “3” when the battery level is half (HALF), “20” when the operation mode is focus and the battery level is zero (END), and the battery level is low. It is “15” when near zero (NEND), “12” when the remaining battery level is half (HALF), and the AD value when the operation mode is zoom is because the lens unit 1 is a fixed focus method. “-” Not set, “15” when the operation mode is video recording and the remaining battery level is zero (END), “10” when the remaining battery level is near zero (NEND), It is “8” when the remaining amount is half (HALF)Note that description of mode A and mode B is omitted here for the sake of simplicity.

  The AD value stored in the unique data storage means of the lens unit 3 ′ is “5” when the operation mode is monitoring and the remaining battery level is zero (END). NEND) is “2”, the battery level is “2” when the battery level is half (HALF), “10” when the operation mode is focus and the battery level is zero (END). Is “6” when the battery is near zero (NEND), “5” when the remaining battery level is half (HALF), and “20” when the operation mode is zoom and the remaining battery level is zero (END). , "15" when the battery level is near zero (NEND), "10" when the battery level is half (HALF), the operation mode is movie recording, and the battery level is zero (END) ) Is “8”, the battery level is near zero (NEND) 4 ", which is when the remaining amount of the battery is half of (HALF)" 3 ".

  The AD value table management as the imaging system 1 is performed by the CPU 202 of the body unit 2 as described above. When the lens unit 3 is attached to the body unit 2, the CPU 202 performs calculation for each operation mode and for each remaining battery level based on the AD value of the lens unit 3 and the AD value of the body unit 2.

  That is, the CPU 202 obtains threshold information ENV with a battery remaining amount of zero (END) when the operation mode is monitoring, “300−10 = 290”, and when the operation mode is focus, “300− When “20 = 280” and the operation mode is moving image recording, an operation of “300−15 = 285” is performed.

  Further, the CPU 202 obtains threshold information NEV in the vicinity of the battery remaining amount of zero (NEND) “400-5 = 395” when the operation mode is monitoring, and “400 when the operation mode is focus. When “-15 = 385” and the operation mode is moving image recording, an operation of “400-10 = 390” is performed.

  Further, the CPU 202 obtains threshold information HAV with the remaining battery level being half (HALF) when the operation mode is monitoring, “500-3 = 497”, and when the operation mode is focus, “500− When “12 = 488” and the operation mode is moving image recording, the calculation of “500−8 = 492” is performed.

  On the other hand, when the lens unit 3 is removed from the body unit 2 and the lens unit 3 ′ is attached to the body unit 2, the CPU 202 sets the AD value of the lens unit 3 ′ and the AD value of the body unit 2. Based on each operation mode, calculation is performed for each remaining battery level.

  That is, the CPU 202 obtains threshold information ENV with a battery remaining amount of zero (END) when the operation mode is monitoring, “300-5 = 295”, and when the operation mode is focus, “300− 10 = 290 ”,“ 300−20 = 280 ”when the operation mode is zoom, and“ 300−8 = 292 ”when the operation mode is moving image recording.

  Further, the CPU 202 obtains threshold information NEV in the vicinity of the battery remaining amount of zero (NEND) “400-2 = 398” when the operation mode is monitoring, and “400-2 = 398” when the operation mode is focus. 400-6 = 394 ”,“ 400-15 = 385 ”when the operation mode is zoom, and“ 400-4 = 396 ”when the operation mode is moving image recording.

Further, the CPU 202 obtains threshold information HAV with the remaining battery level being half (HALF) when the operation mode is monitoring, “500-2 = 498”, and when the operation mode is focus, “500− 5 = 495 ”,“ 500−10 = 490 ”when the operation mode is zoom, and“ 500−3 = 497 ”when the operation mode is moving image recording.
Based on these calculation results, the CPU 202 determines whether or not the remaining battery level is equal to or less than a threshold value for each operation mode, and displays the remaining battery level. Moreover, you may notify with an audio | voice with this display.

  The CPU 202 detects the actual AD value, and when the actual AD value is equal to or less than the threshold obtained by calculation corresponding to each operation mode, the OSD display screen (on-screen display) of the LCD 224 or EVF 225 (image display means) ) Is changed to display the remaining battery level information in addition to the through image or the reproduced image. Thereby, the determination result of the state of the power supply according to the operation in the operation mode is provided to the user. Hereinafter, an example thereof will be described with reference to a flowchart.

(Description of an example of calculation of threshold information of the CPU 202)
When an arbitrary lens unit is attached to the body unit 2, the CPU 202 performs a battery check process as shown in FIG. 8, and acquires the actually detected power supply voltage V (S.1). Here, description will be made assuming that the lens unit 3 is attached to the body unit 2 and is in the monitoring operation mode.

  Based on the AD value “500” as basic load information of the HALF of the body unit 2 and the AD value “3” as specific load information regarding the corresponding operation mode (monitoring operation mode) of the lens unit 3, threshold information on HALF HAV is calculated (S.2). Next, the CPU 2 determines whether or not the actually detected power supply voltage V exceeds the threshold information HAV (S.3).

  When the power supply voltage V exceeds the threshold information HAV (NO), a FULL mark display process is performed (S.4). Return to 1 and continue processing. As a result, as shown in FIG. 9A, the full charge mark as the battery remaining amount information is displayed on the through image or the reproduced image on the OSD display screen G1 (on-screen display) of the LCD 224 or EVF 225 (image display means). In addition, it is displayed. When the power supply voltage V is equal to or lower than the threshold information HAV (when YES), the CPU 202 is specific to the AD value “400” as NEND basic load information of the body unit 2 and the operation mode (monitoring operation mode) of the lens unit 3. Based on the AD value “5” as the load information, threshold information NEV related to NEND is calculated (S.5).

  Next, the CPU 202 determines whether or not the actually detected power supply voltage V exceeds the threshold information NEV (S.6). When the power supply voltage V exceeds the threshold information NEV (NO), a HALF mark display process is performed (S.7). Return to 1 and continue processing. As a result, as shown in FIG. 9B, the display content of the OSD display screen G1 is changed, and the HALF mark as the remaining battery information is displayed in addition to the through image or the reproduced image.

  When the power supply voltage V is equal to or lower than the threshold value information NEV (when YES), the CPU 202 is specific to the AD value “300” as the END basic load information of the body unit 2 and the operation mode (monitoring operation mode) of the lens unit 3. Based on the AD value “10” as the load information, threshold information ENV related to END is calculated (S.8). Next, the CPU 2 determines whether or not the actually detected power supply voltage V exceeds the threshold information ENV (S.9).

  When the power supply voltage V exceeds the threshold information ENV (NO), a NEND mark display process is performed (S.10). Return to 1 and continue processing. As a result, as shown in FIG. 9C, the display content of the OSD display screen G1 is changed, and the NEND mark as the battery remaining amount information is displayed in addition to the through image or the reproduced image.

  When the power supply voltage V is equal to or lower than the threshold information ENV (when YES), the CPU 202 performs an END mark display process (S.11). As a result, as shown in FIG. 9D, the display content of the OSD display screen G1 is changed, and the remaining battery information is displayed in addition to the through image or the reproduced image. Next, the CPU 202 performs a process for terminating the execution of the operation sequence (a process for executing the power supply termination sequence) (S.12).

  The same processing flow is executed in another operation mode, and the same is true when another lens unit is attached to the body unit.

  As described above, in the imaging system according to the embodiment of the present invention, the threshold information necessary for determining the state of the power source is obtained by performing the difference calculation between the basic load information and the specific load information, and the threshold information and the actual load information are actually obtained. The remaining battery level is evaluated on the basis of the detected power supply state, and it is determined whether or not the operation in each operation mode is possible. When the remaining battery level is exhausted, the CPU 202 performs a process of executing a power supply end sequence together with an end display.

  The lens unit is given identification information of the lens unit, but the imaging system is unique even if it does not receive the identification information of whether the lens unit is the lens unit 3 or the lens unit 3 ′, for example. If the load information (differential load information) can be received, the CPU 202 can calculate the threshold information, so that the battery check system functions normally, and the battery remaining amount information can be displayed normally.

Further, even when a lens unit to which no specific load information is given is attached to the body unit, threshold information for each operation mode can be acquired based on the basic load information that the body unit 2 has. The operation of lens units not given is also guaranteed.
That is, when the specific load information cannot be obtained, it is assumed that the information of the AD value “0” is obtained as the specific load information. In this case, since the imaging system operates for each operation mode with a high threshold voltage, the imaging system operates safely without any trouble.

Even if a new body unit 2 or the like is sold, the AD value for each operation mode for the new body unit 2 can be obtained by using a means such as a purchaser uploading by firmware at the first connection to the new body unit. Is stored in the flash ROM 120 as a fixed storage means of the lens unit connected to the new body unit 2, so that the inherent load of the connected lens unit can be changed without changing the basic load information of the new body unit 2. Only by newly storing the differential load information for the new body unit 2 as information, an appropriate battery remaining amount display can be provided.
Therefore, according to this imaging system, the power consumption and control method of the entire imaging system can be achieved by combining the lens unit integrally including the imaging element and the lens unit with the body unit to which the lens unit is not attached. Thus, it is possible to solve the inconsistency in the battery remaining amount display caused by the difference between the two, and to provide the user with an appropriate battery remaining amount display.

  In other words, by fixing the battery table of the body unit and receiving information on the battery table of the lens unit related to imaging as differential load information from the lens unit, the battery suitable for the user as the same single camera as the conventional imaging system The remaining amount mark and normal camera operation can be guaranteed.

  When the battery of the body unit 2 is changed from a lithium ion battery to an alkaline battery or a nickel ion battery, the basic load information about the lithium ion battery of the body unit 2 is changed to the basic load information corresponding to the type of the battery. By doing so, the same arithmetic processing can be performed. Similar calculation processing can also be performed by changing the specific load information of the lens unit to specific load information corresponding to the type of the battery.

  In the above embodiment, only the load information of only one kind of still image reproduction mode is stored in the basic data storage means as basic load information in the body unit 2, but as shown in FIG. Two types of basic load information, that is, load information in the image reproduction mode and load information in the zoom operation mode and the moving image recording mode may be stored. In FIG. 10, load information for monitoring, focus, and still image playback modes is “300”, “400”, and “500”, and basic load information for zoom operation mode and movie recording mode is “340” and “440”. , “540” is set as an example.

  In general, since the power consumption of each operation mode of the body unit 2 itself is different, it corresponds to at least load information corresponding to a reproduction mode for reproducing and displaying a recorded image and a monitoring mode for displaying a through image. The basic data storage unit may store the load information, the load information corresponding to the still image recording mode for capturing a still image, and the load information corresponding to the moving image recording mode for capturing a moving image as basic load information. .

  Also, the lens unit stores at least the differential load information corresponding to the monitoring mode, the differential load information corresponding to the still image recording mode, and the differential load information corresponding to the moving image recording mode in the unique data storage means. It is also good.

  In addition to the lens unit 3 and 3 ′ shown in FIG. 2, the mounting unit 2A of the body unit 2 shown in FIG. 1 includes the projector unit 4 shown in FIG. 11 and the hard disk unit 5 shown in FIG. 13, the wireless unit 6 shown in FIG. 13, the printer unit shown in FIG. 14, the scanner unit 7, and other imaging-related units such as a sensing unit such as an endoscope provided with an imaging unit at the end of the tube. is there.

  Even in this case, by storing the differential load information as unique load information in the unique data storage unit of the imaging related unit, appropriate threshold information can be provided as a whole system when the imaging related unit is attached to the body unit.

DESCRIPTION OF SYMBOLS 1 ... Imaging system 2 ... Body unit 3, 3 '... Lens unit

JP 2008-28655 A

Claims (20)

An interchangeable lens type imaging system comprising a lens unit and a body unit to which the lens unit can be attached and detached,
The body unit is a basic data for storing a plurality of basic load information corresponding to a power source, an image display means for displaying a through image or a reproduced image, a single operation of the body unit, and an operation when the lens unit is mounted. Storage means and communication means for communicating with the lens unit;
The lens unit communicates with the body unit, an imaging optical system, an imaging unit that photoelectrically converts a subject image, a specific data storage unit that stores a plurality of specific load information according to the operation of the lens unit, and the body unit. Means,
When any lens unit is mounted on the body unit, the body unit acquires the inherent load information stored in the inherent data storage means via the both communication means, and corresponds to the operation mode. The threshold information necessary to determine the power supply state is calculated from the basic load information and the specific load information to be operated, and whether or not the operation of the operation mode is possible based on the threshold information and the actually detected power supply state An interchangeable-lens imaging system characterized in that is determined.   When the arbitrary lens unit is attached to the body unit, the image display means displays the determination result of the power supply state according to the operation in the operation mode in addition to the through image or the reproduced image. 2. The interchangeable lens imaging system according to claim 1, wherein the imaging system is displayed.   3. The interchangeable lens imaging system according to claim 1, wherein the basic load information and the specific load information are A / D conversion values related to a voltage of the power supply. 4.   The basic load information and the specific load information are stored as natural numbers including 0, and a value obtained by subtracting the A / D conversion value of the specific load information from the A / D conversion value of the basic load information is an operation in the operation mode. 4. The interchangeable-lens imaging system according to claim 3, wherein the imaging system corresponds to an A / D conversion value of the threshold value information corresponding to the threshold value. The basic load information of the body unit includes at least information corresponding to a still image reproduction mode for reproducing and displaying a recorded image, information corresponding to a monitoring mode for displaying a through image, and a still image recording mode for photographing a still image. Corresponding information and information corresponding to a video recording mode for shooting a video,
The specific load information of the lens unit includes at least information corresponding to the monitoring mode, information corresponding to the still image recording mode, and information corresponding to the moving image recording mode. The interchangeable lens imaging system according to any one of claims 4 to 4.   6. The interchangeable lens type imaging system according to claim 1, wherein the basic data storage means has basic load information corresponding to a type of the power source. An interchangeable lens type imaging system comprising a lens unit and a body unit to which the lens unit can be attached and detached,
The body unit communicates with a power source, image display means for displaying a through image or a reproduced image, basic data storage means for storing basic load information corresponding to a single operation of the body unit, and the lens unit. Communication means,
The lens unit communicates with the body unit, an imaging optical system, an imaging unit that photoelectrically converts a subject image, a specific data storage unit that stores a plurality of specific load information according to the operation of the lens unit, and the body unit. Means,
In the body unit, calculation means for obtaining threshold information necessary for determining the state of the power source by performing a difference calculation between the basic load information and the specific load information, and actually detecting the threshold information. An interchangeable lens type imaging system, comprising: a determination unit that determines whether the operation is possible for each of the operation modes based on the state of the power supply.   8. The interchangeable lens imaging system according to claim 7, wherein the single operation is a still image reproduction mode, and the basic load information is load information of the still image reproduction mode.   9. The interchangeable lens imaging system according to claim 8, wherein the specific load information is differential load information between the basic load information and the threshold information.   The interchangeable lens imaging system according to claim 9, wherein the differential load information is set for each operation mode of the camera.   The operation mode of the lens unit corresponds to at least differential load information corresponding to a monitoring mode for displaying a through image, differential load information corresponding to a still image recording mode for capturing a still image, and a moving image recording mode for capturing a moving image. The interchangeable lens imaging system according to claim 10, wherein the information is differential load information.   When the arbitrary lens unit is attached to the body unit, the image display means displays the determination result of the state of the power source according to the operation in each operation mode in addition to the through image or the reproduced image. 12. The interchangeable-lens imaging system according to claim 11, wherein is displayed.   The interchangeable-lens imaging system according to claim 12, wherein the basic load information, the specific load information, and the threshold information are A / D conversion values related to the voltage of the power supply.   An imaging-related unit other than the lens unit can be attached to and detached from the body unit, and the imaging-related unit stores unique load information that is a difference between the still image reproduction mode information and the threshold information, and the imaging unit The related unit is a projector unit that projects an image recorded on the body unit, a high-capacity recording medium unit that can record and reproduce image data, or a wireless unit that transmits image data recorded on the body unit or a sensing device. 9. The interchangeable-lens imaging system according to claim 8, wherein the imaging system is interchangeable. A lens unit having a photographing optical system, an image pickup means for photoelectrically converting a subject image, and a unique data storage means for storing a plurality of unique load information corresponding to the operation mode, and at least one of the operation modes being different is removable. A body unit,
A power source, an image display means for displaying a through image or a reproduction image, a basic data storage means for storing basic load information corresponding to a still image reproduction mode, a communication means for communicating with the lens unit, and the basic load. Imaging based on the threshold information necessary for determining the power supply state by performing a difference calculation between the information and the specific load information, and the threshold information and the actually detected power supply state A body unit, comprising: a determination unit that determines whether the operation is possible for each operation mode of the entire system.   When an arbitrary lens unit is mounted, the image display means displays the determination result of the power supply state according to the operation in the operation mode in addition to the through image or the reproduced image. The body unit according to claim 15, characterized in that A power source, an image display means for displaying a through image or a reproduced image, a basic data storage means for storing basic load information corresponding to a still image reproduction mode, and a state of the power supply based on the basic load information. Computation means for obtaining necessary threshold information, and judgment means for judging whether or not the operation is possible for each of the operation modes of the entire imaging system based on the threshold information and the actually detected power supply state are provided. A lens that can be attached to and detached from the body unit,
An imaging optical system; an imaging unit that photoelectrically converts a subject image; a unique data storage unit that stores a plurality of specific load information according to operation; and a communication unit that communicates with the body unit; The lens unit, wherein the load information is differential load information between the threshold information and the basic load information necessary for determining the state of the power source.   The unique data storage means corresponds to differential load information corresponding to at least a monitoring mode for displaying a through image, differential load information corresponding to a still image recording mode for capturing a still image, and a moving image recording mode for capturing a moving image. 18. The lens unit according to claim 17, wherein differential load information is stored. A power source; image display means for displaying a through image or a reproduced image; basic data storage means for storing basic load information corresponding to a single operation of the body unit; and communication means for communicating with the lens unit. A body unit,
A lens having an imaging optical system, imaging means for photoelectrically converting a subject image, unique data storage means for storing a plurality of unique load information corresponding to the operation of the lens unit, and communication means for communicating with the body unit Unit,
A method for evaluating the remaining battery level used in an interchangeable lens imaging system comprising:
Threshold information necessary to determine the state of the power supply by performing a difference calculation between the basic load information and the specific load information is obtained, and based on the threshold information and the actually detected power supply state A method for evaluating a remaining battery level of an interchangeable lens type imaging system, wherein whether or not the operation is possible is determined for each operation mode.   The single operation is a still image reproduction mode, the basic load information is load information of the still image reproduction mode, and the differential load information corresponding to a monitoring mode in which the operation mode of the lens unit displays at least a through image; The interchangeable lens type imaging according to claim 19, wherein the load information is differential load information corresponding to a still image recording mode for capturing a still image and differential load information corresponding to a moving image recording mode for capturing a moving image. A method for evaluating the battery level of the system

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