JP4213875B2 - Image storage system, image storage method, image transfer apparatus, and image capturing apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image storage system, an image storage method, an image transfer apparatus, and an image capturing apparatus. In particular, the present invention relates to an image storage system and an image storage method for storing an image in a storage medium provided in the image pickup apparatus, and an image transfer apparatus and an image pickup apparatus used therefor.
[0002]
[Prior art]
The image capturing apparatus stores an image captured by the image capturing unit in a storage medium such as a magnetic recording medium, a magneto-optical recording medium (MO), or a semiconductor memory. The stored image is captured and processed by, for example, a personal computer, and then displayed and reproduced on a monitor or printed out in a laboratory.
[0003]
[Problems to be solved by the invention]
On the other hand, some storage media previously store additional images such as advertisement images. Here, when storing an advertisement image or the like in a storage medium, conventionally, the storage medium such as a memory card is taken out of the image pickup device and inserted into a card slot of a personal computer or the like, and the advertisement image or the like is stored in a memory card or the like. I remembered it and was troublesome.
[0004]
Therefore, an object of the present invention is to provide an image storage system, an image storage method, an image transfer apparatus, and an image capturing apparatus that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.
[0005]
[Means for Solving the Problems]
In other words, an image storage system according to the first aspect of the present invention is an image storage system that includes an image capturing device and an image transfer device, and stores an image in a storage medium provided in the image capturing device. The apparatus includes an image transfer unit that transfers an image to the image capturing apparatus. The image capturing apparatus houses a storage medium in the casing and receives an image transferred from the image transfer apparatus. An image receiving unit disposed inside the image receiving unit, and a control unit that stores an image received by the image receiving unit in a storage medium.
[0006]
In the image storage system of the present invention, the image pickup device preferably includes a printed circuit board on which an electric circuit is formed in a pattern, and the storage medium is soldered on the printed circuit board.
[0007]
In the image storage system of the present invention, the image transfer device has a storage unit that can store a part of the image pickup device, and the image receiving unit is in a state in which a part of the image pickup device is stored in the storage unit. The image transferred from the image transfer apparatus may be received.
[0008]
In the image storage system of the present invention, the storage unit has an output terminal that outputs an electrical signal representing an image, and the image imaging device includes an output terminal in a state where a part of the image imaging device is stored in the storage unit. An input terminal that can be fitted to the output terminal is provided on one side surface of the corresponding housing, and the image receiving unit may receive an electrical signal transferred via the output terminal and the input terminal.
[0009]
In the image storage system of the present invention, the image transfer unit has a radio signal conversion unit that converts an electrical signal representing an image into a radio signal and outputs the radio signal, and the radio signal converted by the radio signal conversion unit is converted into an image. The image capturing device is provided with a radio wave transmitting unit that transmits radio waves through the housing on one side surface of the image capturing device, and the image receiving unit is emitted from the radio signal conversion unit and transmits radio waves. It is preferable to include a reception unit that receives a radio signal transmitted through the unit and an image signal conversion unit that converts the radio signal received by the reception unit into an electrical signal representing an image.
[0010]
In the image storage system of the present invention, the image transfer unit has an optical signal conversion unit that converts an electrical signal representing an image into an optical signal and outputs the optical signal, and images the optical signal converted by the optical signal conversion unit. The image pickup apparatus is provided with a light transmission portion that transmits light through the housing on one side surface of the housing, and the image receiving section is emitted from the optical signal conversion section. It is preferable to include a light receiving unit that receives an optical signal transmitted through the light receiving unit and an image signal conversion unit that converts the optical signal received by the light receiving unit into an electrical signal representing an image.
[0011]
An image storage method according to a second aspect of the present invention is an image storage method for storing an image in a storage medium housed inside a housing of an image capturing apparatus, and images are captured outside the housing. An image transfer device for transferring to the device is provided, an image transferred from the image transfer device is received by an image receiving unit provided inside the housing, and an image received by the image receiving unit is stored in a storage medium.
[0012]
An image transfer apparatus according to a third aspect of the present invention is an image transfer apparatus that transfers an image to be stored in a storage medium accommodated in a housing of the image pickup apparatus to the image pickup apparatus, and A storage unit that can store a part of the apparatus, and an image transfer unit that transfers an image to the image capturing apparatus in a state where a part of the image capturing apparatus is stored in the storage unit.
[0013]
In the image transfer apparatus according to the present invention, the housing section may have an output terminal that outputs an electrical signal representing an image.
[0014]
In the image transfer device of the present invention, the image transfer unit has a radio signal conversion unit that converts an electrical signal representing an image into a radio signal and outputs the radio signal, and images the radio signal converted by the radio signal conversion unit. It may be transferred to the device.
[0015]
In the image transfer apparatus of the present invention, the image transfer unit has an optical signal conversion unit that converts an electrical signal representing an image into an optical signal and outputs the optical signal, and the optical signal converted by the optical signal conversion unit is an image pickup device It is good to forward to.
[0016]
An image pickup apparatus according to a fourth aspect of the present invention includes an image pickup unit that picks up a subject image, and an image transfer apparatus arranged outside a housing on a storage medium housed inside the housing. An image pickup device for storing a transferred image, the image receiving unit disposed inside the housing for receiving the image transferred from the image transfer device, and the image received by the image receiving unit as a storage medium And a control unit to be stored.
[0017]
In the image pickup device of the present invention, the image receiving unit receives an image transferred from the image transfer device in a state where a part of the image pickup device is stored in the storage unit provided in the image transfer device. Good.
[0018]
In the image pickup device of the present invention, in a state where a part of the image pickup device is housed in the housing portion, on one side surface of the housing corresponding to the output terminal that outputs an electrical signal representing the image provided in the housing portion. The image receiving unit may receive an electric signal transferred from the image transfer apparatus via the input terminal.
[0019]
In the image pickup apparatus of the present invention, a radio wave transmission unit that transmits radio waves through the housing is provided on one side surface of the housing, and the image receiving unit converts an electrical signal representing an image in the image transfer device. A reception unit that receives the radio signal transmitted through the radio wave transmission unit, and an image signal conversion unit that converts the radio signal received by the reception unit into an electrical signal representing an image. Good.
[0020]
In the image pickup apparatus of the present invention, the receiving unit may be provided so that the receiving surface faces the radio wave transmitting unit.
[0021]
In the image pickup device of the present invention, a light transmission unit that transmits light through the housing is provided on one side surface of the housing, and the image receiving unit converts an electrical signal representing an image in the image transfer device. A light receiving unit that receives the optical signal obtained through the light transmission unit, and an image signal conversion unit that converts the optical signal received by the light receiving unit into an electrical signal representing an image. Good.
[0022]
In the image pickup apparatus of the present invention, the light receiving unit may be provided such that the light receiving surface faces the light transmitting unit.
[0023]
The image pickup apparatus of the present invention further includes a main power source that operates the image pickup unit and a sub power source that has a power supply capability smaller than that of the main power source, and the image receiving unit and the control unit supply power from the sub power source. The image may be stored in the storage medium by operating in response.
[0024]
The image pickup apparatus of the present invention may further include a second storage medium that stores nonvolatile information, and the second storage medium may operate by receiving power supplied from the sub power source.
[0025]
In the image pickup apparatus of the present invention, a power supply to a detection unit that detects whether a signal representing an image has been transferred from the image transfer apparatus to the image pickup apparatus, and to a storage medium, an image receiving unit, and a control unit Is switched to either the main power source or the sub power source, and switches to the sub power source side on condition that the detection unit detects that the image has been transferred from the image transfer device to the image capturing device. It is good to have a power supply switching part.
[0026]
In the image capturing apparatus of the present invention, the detection unit detects whether or not the signal representing the image has been transferred to the image capturing apparatus by detecting the signal representing the image transferred from the image transfer apparatus and passed through the housing. It is good to detect.
[0027]
In the image pickup apparatus of the present invention, the signal line and the control line to the storage medium are transferred image recording side for storing the image transferred from the image transfer apparatus, and the subject image captured by the image pickup apparatus is stored. A switching unit that switches to one of the subject image recording side for storing, on the condition that the detection unit detects that the image has been transferred from the image transfer device to the image capturing device. It is preferable to further include a signal control line switching unit for switching to.
[0028]
The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the claimed invention, and all combinations of features described in the embodiments are the solution of the invention. It is not always essential to the means.
[0030]
FIG. 1 is an external view of a digital camera 10 according to the first embodiment as an example of an image capturing apparatus. FIG. 1 (A) is an imaging surface, FIG. 1 (B) is an operation surface, and FIG. Show the side. The main members of the digital camera 10 are a substantially concave first housing (front cover) 202 mainly responsible for the imaging surface side and a substantially concave second housing (rear cover) 204 mainly responsible for the operation surface side. It is accommodated in the concave shape, and the edges of the two casings 202 and 204 are fitted together. Hereinafter, the first casing 202 and the second casing 204 are collectively referred to as a casing 200.
[0031]
After the main member is accommodated and assembled, the outside of the housing 200 is free of the photographing lens 22 on the imaging surface side, and the LCD monitor 102, the power switch 112, and the operation switches 116a and 116b on the operation surface side. In order to be in a state, it is wrapped in a predetermined shape of the exterior paper 210.
[0032]
On the imaging surface side of the exterior paper 210, index information indicating the content of the additional image stored in advance in a storage medium (image memory) 177 housed in the housing 200 and an image relating to the sales location are printed. . Note that the additional image stored in advance in the storage medium 177 is an image different from the subject image captured by the imaging unit 20. For example, the storage medium 177 stores an image related to the main sales area (local area) of the digital camera 10 as an example of the additional image, for example, an image indicating local information, in at least a part of the storage area. For example, when the sales place is a tourist spot, the image indicating the local information may be images of various tourist spots. In the example shown in FIG. 1A, an image relating to “Nagoya”, which is the main sales place of this digital camera 10, is stored as an additional image, and accordingly, characters indicating “Nagoya” are used as index information, and Nagoya Castle Are printed as images relating to sales places. The image relating to “Nagoya” stored in the storage medium 177 as the additional image is, for example, an image of a tourist spot in Nagoya or an advertisement image of a souvenir shop or an accommodation facility.
[0033]
Information indicating a procedure for operating the digital camera 10 is printed on the operation surface side of the exterior paper 210.
[0034]
An input terminal 140 for inputting an image signal representing an additional image into the digital camera 10 is provided on the side surface of the housing 200. The input terminal 140 is provided on one side surface of the housing 200 corresponding to the output terminal provided in the accommodating portion in a state where a part of the digital camera 10 is accommodated in the accommodating portion provided in the image transfer apparatus (not shown). It is done. The input terminal 140 can be fitted with an output terminal on the image transfer apparatus side. The input terminal 140 is covered with a sealing member such as a sealing seal 220 so that the user cannot directly touch the input terminal 140. A release switch 114 is provided on the upper surface of the housing 200.
[0035]
FIG. 2 shows main members housed in the housing 200. A main CPU 62, a timer 86, an LCD monitor 102, a sub power supply 122, an input terminal 140, a storage medium 177, and the like are mounted on a main board 170 on which an electric circuit is formed by soldering, and the board assembly 199 is formed. Is formed. In a state where the digital camera 10 is assembled, it is almost impossible for the user to take out the storage medium 177 to the outside of the housing 200.
[0036]
The main power source 120 is, for example, a lithium ion battery. The sub power source 122 is a button type battery such as CR2016, for example. The sub power source 122 has a power supply capability smaller than that of the main power source 120 and a low voltage.
[0037]
Electrode terminals 192 and 194 are provided on the left side of the main substrate 170 in the drawing, and the main power source 120 is mounted between the two electrode terminals 192 and 194 when assembled. On the other hand, the imaging unit 20 is mounted on the main board 170 via the terminals 22a and 22b when assembled.
[0038]
FIG. 3 is a functional block diagram of the digital camera 10 according to the first embodiment. The digital camera 10 includes a digital still camera, a digital video camera that can capture a still image, and the like. The digital camera 10 mainly includes an imaging unit 20, which is an example of an imaging unit of the present invention, an imaging control unit 40, a processing unit 60, a display unit 100 which is an example of an image display unit of the present invention, an operation unit 110, and a power supply circuit. 128.
[0039]
The digital camera 10 includes a main power source 120 that operates the imaging unit 20 by supplying power via a power circuit 128. The main power supply 120 supplies power to the imaging control unit 40, the processing unit 60, the display unit 100, and the operation unit 110 in addition to the imaging unit 20. The processing unit 60 includes a sub power source 122 whose power supply capability is smaller than that of the main power source 120.
[0040]
The imaging unit 20 includes a mechanism member and an electrical member related to shooting and imaging. The imaging unit 20 first includes a photographic lens 22 that captures and processes an image, a diaphragm 24, a shutter 26, an optical LPF (low-pass filter) 28, a CCD 30 that is an example of a solid-state imaging device, and an imaging signal processing unit 32. The solid-state imaging device is not limited to the CCD 30 and may be, for example, a C-MOS type sensor.
[0041]
The photographing lens 22 includes a focus lens and a zoom lens. With this configuration, a subject image is formed on the light receiving surface of the CCD 30. Charges are accumulated in each sensor element of the CCD 30 (not shown) according to the amount of light of the formed subject image. Hereinafter, this charge is referred to as accumulated charge. The accumulated charge is read to a shift register (not shown) by a read gate pulse, and sequentially read as an analog voltage signal by a register transfer pulse.
[0042]
Since the digital camera 10 generally has an electronic shutter function, a mechanical shutter such as the shutter 26 is not essential. In order to realize the electronic shutter function, the CCD 30 is provided with a shutter drain via a shutter gate. When the shutter gate is driven, the accumulated charge is swept out to the shutter drain. By controlling the shutter gate, the time for accumulating charges in each sensor element, that is, the shutter speed can be controlled.
[0043]
The analog voltage signal output from the CCD 30 is color-separated into R, G, and B components by the imaging signal processing unit 32, and first the white balance is adjusted. Subsequently, the imaging signal processing unit 32 performs gamma correction, sequentially A / D-converts each of the R, G, and B signals at a necessary timing, and digital image data obtained as a result (hereinafter referred to as digital image data). Is output to the processing unit 60.
[0044]
The imaging unit 20 further includes a finder 34 and a strobe 36. The finder 34 may be equipped with an LCD (not shown). In this case, various types of information from the main CPU 62 described later can be displayed in the finder 34. The strobe 36 functions by emitting light when energy stored in a capacitor (not shown) is supplied to the discharge tube 36a.
[0045]
The imaging control unit 40 includes a zoom driving unit 42, a focus driving unit 44, an aperture driving unit 46, a shutter driving unit 48, an imaging system CPU 50 that controls them, a distance measuring sensor 52, and a photometric sensor 54. Each of the driving units such as the zoom driving unit 42 has driving means such as a stepping motor. In response to depression of a later-described release switch (shutter switch) 114, the distance measuring sensor 52 measures the distance to the subject, and the photometric sensor 54 measures the subject brightness. The measured distance data (hereinafter referred to as distance measurement data) and the subject brightness data (hereinafter referred to as photometry data) are sent to the imaging system CPU 50. The imaging system CPU 50 adjusts the zoom magnification and focus of the photographing lens 22 by controlling the zoom driving unit 42 and the focus driving unit 44 based on the photographing information such as the zoom magnification designated by the user (operator). The imaging system CPU 50 may control the zoom driving unit 42 to move the position of the imaging lens 22 in order to capture a parallax image.
[0046]
The imaging system CPU 50 determines the aperture value and shutter speed based on the RGB digital signal integrated value of one image frame, that is, AE information. According to the determined value, the aperture driving unit 46 and the shutter driving unit 48 adjust the aperture amount and open / close the shutter 26, respectively.
[0047]
The imaging system CPU 50 also controls the light emission of the strobe 36 based on the photometric data, and simultaneously adjusts the aperture amount of the aperture 26. When the user instructs to capture an image, the CCD 30 starts to accumulate charges, and the accumulated charges are output to the imaging signal processing unit 32 after the shutter time calculated from the photometric data has elapsed.
[0048]
The processing unit 60 includes a main CPU 62 that controls the entire digital camera 10, particularly the processing unit 60 itself, a memory control unit 64, a YC processing unit 70, a compression / decompression processing unit 78, a communication I / F unit 80, And a clock generator 88.
[0049]
An option device control unit 74 may be provided, and a memory card, which is an example of a storage medium for storing images, may be mounted as a type of option device 76.
[0050]
The main CPU 62 exchanges necessary information with the imaging CPU 50 by serial communication or the like. The operation clock of the main CPU 62 is given from the clock generator 88. The clock generator 88 also provides clocks with different frequencies to the imaging system CPU 50 and the display unit 100, respectively.
[0051]
The main CPU 62 is provided with a character generation unit 84 and a timer 86. The timer 86 is operated by being backed up by the sub power source 122, and always counts the date and time as an example of nonvolatile information. From this count value, information on the shooting date and time information and other time information are given to the main CPU 62. The character generation unit 84 generates character information such as a shooting date / time and a title, and the character information is appropriately combined with the shot image.
[0052]
The main CPU 62 first stores at least one advertisement image from the storage medium 177 when the subject image captured by the imaging unit 20 is stored in the same area as the storage area in the storage medium 177 where the advertisement image is stored. The data is read and displayed on the display unit 100. Thereafter, the main CPU 62 stores the subject image in the same area as the storage area of the displayed advertisement image in the storage medium 177, on condition that image storage in the storage medium 177 is permitted.
[0053]
The memory control unit 64 controls the nonvolatile memory 66 and the main memory 68. The non-volatile memory 66 includes an EEPROM (electrically erasable and programmable ROM), a FLASH memory, and the like, and should be retained even when the power of the digital camera 10 is turned off, such as user setting information and factory adjustment values. Data is stored. In some cases, the non-volatile memory 66 may store a boot program or a system program for the main CPU 62. On the other hand, the main memory 68 is generally composed of a relatively inexpensive memory having a large capacity, such as a DRAM. The main memory 68 has a function as a frame memory for storing data output from the imaging unit 20, a function as a system memory for loading various programs, and other functions as a work area. The nonvolatile memory 66 and the main memory 68 exchange data with each part inside and outside the processing unit 60 via the main bus 82.
[0054]
The YC processing unit 70 performs YC conversion on the digital image data, and generates a luminance signal Y and color difference (chroma) signals BY and RY. The luminance signal and the color difference signal are temporarily stored in the main memory 68 by the memory control unit 64. The compression / decompression processor 78 sequentially reads out the luminance signal and the color difference signal from the main memory 68 and compresses them. The subject image data thus compressed (hereinafter referred to as compressed data) is stored (written) in a predetermined storage area of the storage medium 177. Note that the data may be stored in a predetermined storage area of a memory card mounted as a kind of option device 76 via the option device control unit 74.
[0055]
The processing unit 60 further has an encoder 72. The encoder 72 receives the luminance signal and the color difference signal, converts them into a video signal (NTSC or PAL signal), and outputs the video signal from the video output terminal 90. When a video signal is generated from data recorded in the option device 76, the data is first supplied to the compression / decompression processing unit 78 via the option device control unit 74. Subsequently, the data that has undergone the necessary expansion processing in the compression / expansion processing unit 78 is converted into a video signal by the encoder 72.
[0056]
The optional device controller 74 performs necessary signal generation, logic conversion, voltage conversion, or the like between the main bus 82 and the storage medium 177 in accordance with the signal specifications recognized for the storage medium 177 and the bus specifications of the main bus 82. .
[0057]
The digital camera 10 may support a standard I / O card conforming to PCMCIA, for example, in addition to the memory card described above as the optional device 76. In this case, the option device control unit 74 may be configured by a PCMCIA bus control LSI or the like.
[0058]
The communication I / F unit 80 performs control such as protocol conversion according to communication specifications supported by the digital camera 10, such as USB, RS-232C, Ethernet (registered trademark), Bluetooth, IrDA, and the like. The communication I / F unit 80 includes a driver IC as necessary, and communicates with an external device including a network via the connector 92. In addition to such standard specifications, for example, a configuration may be adopted in which data is transmitted and received by an original I / F with external devices such as a printer, a karaoke machine, and a game machine.
[0059]
Furthermore, the processing unit 60 includes a storage medium 177 and an input terminal 140 that are fixedly disposed on the main board 170 (see FIG. 2). The processing unit 60 also includes an image receiving unit 150 that receives an additional image transferred from the outside of the housing via the input terminal 140, and a storage control unit 160 that stores the additional image received by the image receiving unit 150 in the storage medium 177. Also have. Further, the processing unit 60 supplies power to the storage medium 177, the image receiving unit 150, and the storage control unit 160, and a signal line to the storage medium 177 depending on whether or not the additional image is transferred to the digital camera 10. And an activation control unit 130 for switching control lines.
[0060]
The display unit 100 includes an LCD monitor 102 that is an example of a display device, and an LCD panel 104. They are controlled by a monitor driver 106 and a panel driver 108, which are LCD drivers. The LCD monitor 102 is provided on the back of the camera with a size of about 2 inches, for example, and the current shooting / playback mode, zoom magnification for shooting / playback, battery level, date / time, mode setting screen, subject image, etc. Is displayed. The LCD panel 104 is a small black-and-white LCD provided on the upper surface of the camera, for example, and simply displays information such as image quality (FINE / NORMAL / BASIC, etc.), strobe emission / prohibition of flash, standard number of shoots, number of pixels, battery capacity, etc. .
[0061]
The operation unit 110 includes a mechanism and electrical members necessary for the user to set or instruct the operation of the digital camera 10 and its mode. The power switch 112 determines on / off of the main power supply of the digital camera 10. The release switch 114 has a two-step pushing structure of half-pressing and full-pressing. The main CPU 62 monitors the pressing state of the release switch 114 and determines that, for example, a half-press by the operator (shutter half-press) is a pre-shooting operation, while a full-press by the operator (shutter full-press). Is determined to be an operation of the execution process of shooting. As an example, AF and AE are locked by half-pressing, and a captured image is taken in by full-pressing. After necessary signal processing, data compression, etc., it is recorded in the main memory 68, optional device 76, and the like. In addition to these switches, the operation unit 110 may accept settings using a rotary mode dial, a cross key, and the like, which are collectively referred to as a function setting unit 116 in FIG. Examples of operations or functions that can be specified by the operation unit 110 include “file format”, “special effect”, “print”, “decision / save”, “display switching”, and the like. The zoom switch 118 determines the zoom magnification.
[0062]
FIG. 4 is a block diagram showing details of the activation control unit 130 and its peripheral parts. The activation control unit 130 includes a detection unit 132, a power supply switching unit 134, and a switch unit 139 that is an example of a signal control line switching unit. The detection unit 132 detects whether or not a signal representing the additional image has been transferred into the digital camera 10 from the outside of the housing. In the digital camera 10 of the first embodiment, the detection unit 132 detects whether or not an electrical signal representing an additional image is input to the input terminal 140, thereby transferring a signal representing the additional image to the digital camera 10. It is detected whether it was done. The detection unit 132 may be configured to detect a dedicated electric signal for transferring an electric signal representing the additional image to the digital camera 10.
The power supply switching unit 134 includes a switch 136 and two diodes 137 and 138. A voltage from the power supply circuit 128 is applied to the anode terminal of the diode 137, a voltage from the sub power supply 122 is applied to the anode terminal of the diode 138 via the switch 136, and the cathode terminals are connected to each other. This cathode terminal is connected to each power input terminal of the storage medium 177, the image receiving unit 150, and the storage control unit 160. The switch input terminal of the switch 136 is connected to the output of the detection unit 132. When the detection unit 132 detects that the additional image has been transferred to the digital camera 10, the detection unit 132 turns on the switch 136. The voltage input from the power supply circuit 128 to the diode 137 is higher than the output voltage of the sub power supply 122. Therefore, when the power supply circuit 128 is activated, power is supplied from the main power supply 120 to the storage medium 177, the image receiving unit 150, and the storage control unit 160 even if the switch 136 is turned on. On the other hand, when the power supply circuit 128 is not activated, when the detection unit 132 detects that the additional image has been transferred to the digital camera 10, the storage medium 177, the image reception unit 150, and the storage control are detected from the sub power supply 122. Power is supplied to the unit 160.
[0063]
The switch unit 139 includes a signal line switch 139a and a control line switch 139b. An image signal representing an additional image received by the image receiving unit 150 is input to one input terminal (H) of the signal line switch 139a, and the imaging unit is connected to the other input terminal (L) via the main bus 82. An image signal representing the subject image picked up by 20 is input, and the output terminal (O) is connected to the signal input terminal of the storage medium 177. A control signal from the storage controller 160 is input to one input terminal (H) of the switch 139b for the control line, and a control signal from the main CPU 62 is input to the other input terminal (L). (O) is connected to the control input terminal of the storage medium 177. Accordingly, the terminals on the H side of the switches 139a and 139b become the additional image recording side operable by the sub power source 122 for storing the additional image in the storage medium 177, and the terminals on the L side are other than the additional image. This is the non-additional image recording side operable by the main power source 120 for storing the image (specifically, the subject image) in the storage medium 177.
[0064]
The detection unit 132 switches the switches 139a and 139b to the H side when detecting that the additional image has been transferred to the digital camera 10, and switches to the L side when not detecting. As described above, the switch unit 139 switches the signal line and the control line to the storage medium 177 to one of the operation side by the main power source 120 and the operation side by the sub power source 122 according to the detection result by the detection unit 132. .
[0065]
The main operation of the digital camera 10 configured as described above is as follows. First, when the power switch 112 of the digital camera 10 is turned on, power is supplied from the main power supply 120 to each part of the camera via the power supply circuit 128. When power is supplied, the main CPU 62 reads out an advertisement image as an example of the additional image from the storage medium 177 and displays the advertisement image on the LCD monitor 102. Since the detection unit 132 has not detected that the additional image has been transferred from the image transfer device 300, the detection unit 132 switches the switch unit 139 to the L side (that is, the non-additional image recording side).
[0066]
Next, the main CPU 62 reads the state of the function setting unit 116 to determine whether the digital camera 10 is in the shooting mode or the playback mode. When the digital camera 10 is in the shooting mode, the main CPU 62 monitors the half-pressed state of the release switch 114. When the half-pressed state is detected, the main CPU 62 determines that the user has issued a preprocessing command out of the image capturing commands. First, the photometry data and the distance measurement data from the photometry sensor 54 and the distance measurement sensor 52, respectively. Get the data. Based on the obtained data, the imaging control unit 40 operates to adjust the focus, aperture, etc. of the taking lens 22. When the adjustment is completed, the main CPU 62 displays a processed image in which the characters “standby” are superimposed on the advertisement image, thereby notifying the user that the digital camera 10 is in the “standby” state.
[0067]
The main CPU 62 superimposes the characters “standby” on the actual image captured by the imaging unit 20 after the processed image on which characters “standby” or the like are superimposed is displayed for a predetermined time. A processed image may be displayed. In this case, the user can check not only the “standby” state but also the subject image captured by the imaging unit 20 in a moving image.
[0068]
Subsequently, the main CPU 62 monitors the fully pressed state of the release switch 114. When the release switch 114 is fully pressed, the main CPU 62 determines that the user has issued an execution processing command out of the image capturing commands. Then, the shutter 26 is closed after a predetermined shutter time, and the charge accumulated in the CCD 30 is swept out to the imaging signal processing unit 32. Digital image data generated as a result of processing by the imaging signal processing unit 32 is output to the main bus 82. The digital image data is temporarily stored in the main memory 68, and thereafter processed by the YC processing unit 70 and the compression / decompression processing unit 78, and stored (recorded) in a predetermined storage area of the storage medium 177.
[0069]
For example, the main CPU 62 displays the recorded image on the LCD monitor 102 for a while in a frozen state. In this case, the user can check the photographed subject image. This completes a series of shooting operations.
[0070]
On the other hand, when the digital camera 10 is in the playback mode, the main CPU 62 reads the last photographed image from the main memory 68 via the memory control unit 64 and displays it on the LCD monitor 102 of the display unit 100. In this state, when the user instructs “forward” and “reverse” on the function setting unit 116, the main CPU 62 reads out images taken before and after the currently displayed image from the storage medium 177, and the LCD monitor 102. To display.
[0071]
FIG. 5 shows an embodiment of the image storage system of the present invention. FIG. 5 shows a state almost immediately before a part of the digital camera 10 is attached to the first embodiment of the image transfer apparatus of the present invention.
[0072]
The illustrated image transfer apparatus 300 includes an operation surface 310 and a back panel 320 disposed so as to protrude to the rear side of the operation surface 310. An operation unit 312, an LCD panel 314, and an LCD monitor 316 are disposed on the operation surface 310. A substantially concave accommodating portion 330 is provided on a part of the upper surface of the back panel 320. An output terminal 332 for transferring the additional image to the digital camera 10 is provided in the storage unit 330.
[0073]
As described above, the digital camera 10 has the input terminal 140 that can be fitted to the output terminal 332 on one side surface of the housing 200. In the digital camera 10, a part of the housing 200 is housed in the housing portion 330 such that the input terminal 140 side faces the housing portion 330 side of the image transfer apparatus 300. As a result, the input terminal 140 of the digital camera 10 and the output terminal 332 of the image transfer apparatus 300 are connected.
[0074]
The operation unit 312 is a mechanism (for example, an operation key) necessary for a store selling the digital camera 10 to set or instruct an operation and a mode for storing an additional image in the storage medium 177 of the digital camera 10. And an electrical member.
[0075]
The LCD panel 314 is a small monochrome LCD, for example, and simply displays information such as an operation state in the operation unit 312. The LCD monitor 316 is a color LCD having a size of about 4 inches, for example, and displays an additional image being transferred to the digital camera 10.
[0076]
The additional image transferred to the digital camera 10 may be acquired via the connection line 322 connected to the communication line. Alternatively, it may be obtained via a memory card attached to a slot 324 provided on the front surface of the back panel 320.
[0077]
FIG. 6 is a functional block diagram of the image transfer apparatus 300 according to the first embodiment. The image transfer device 300 includes an image acquisition unit 340 that acquires an additional image, an image transfer unit 350 that transfers the additional image acquired by the image acquisition unit 340 to the digital camera 10 via the output terminal 332, and an image transfer device. And a transfer control unit 360 that controls the operation of each unit in the unit 300. The image transfer unit 350 includes an output amplifier 352 that amplifies the image signal representing the additional image input from the image acquisition unit 340 to a transfer signal level.
[0078]
When the additional image is stored in the storage medium 177 in the digital camera 10 using the image transfer device 300, for example, a sales clerk first holds the digital camera 10 with the power off and a part of the housing 200 in the housing portion 330. Install (contain) inside. Next, in the state where the input terminal 140 of the digital camera 10 and the output terminal 332 of the image transfer apparatus 300 are connected, the image transfer apparatus 300 operates the operation unit 312 by a sales clerk so that an additional image is externally transmitted. The image is acquired by the internal image acquisition unit 340. The sales clerk determines the additional image to be transferred to the digital camera 10 while confirming the captured additional image on the LCD monitor 316.
[0079]
Next, the image transfer apparatus 300 transfers the additional image determined to be transferred when the sales clerk operates the operation unit 312 to the digital camera 10 via the output amplifier 352 and the output terminal 332. Then, the digital camera 10 receives an electrical signal representing the additional image transferred from the image transfer device 300 by an image receiving unit 150 provided inside the housing 200. At the same time, the detection unit 132 detects that the additional image has been transferred from the image transfer apparatus 300, and switches the switch unit 139 to the H side (that is, the additional image recording side). Thereafter, the storage control unit 160 stores the additional image received by the image receiving unit 150 in the storage medium 177.
[0080]
As described above, according to the image storage system of the above embodiment, an advertisement image or the like can be stored in the storage medium 177 while the storage medium 177 is provided in the digital camera 10.
[0081]
FIG. 7 is a side view of the digital camera 10 according to the second embodiment. The difference from the first embodiment is that the additional image transferred from the image transfer apparatus 300 is received in the form of a radio signal. That is, the digital camera 10 of the second embodiment transmits radio waves through the housing 200 at substantially the same position as the side surface of the housing 200 where the input terminal 140 of the digital camera 10 of the first embodiment is provided. It has a radio wave transmitting portion 142 to be operated. The radio wave transmitting unit 142 may be formed of any member as long as it is a member that can transmit a radio wave signal representing an additional image. For example, the opening part which penetrated the housing | casing 200 may be sufficient. In this case, the member is air. Note that the opening may be covered with a radio wave transmitting sealing member.
[0082]
FIG. 8 is a block diagram showing details of the activation control unit 130 and its peripheral part in the digital camera 10 according to the second embodiment. In the digital camera 10 according to the second embodiment, the detection unit 132 detects whether or not a radio wave signal representing an additional image is input via the radio wave transmission unit 142, so that the signal representing the additional image is converted into a digital camera. 10 is detected. The detection unit 132 may be configured to detect a dedicated radio signal indicating that a radio signal representing an additional image is transferred to the digital camera 10.
[0083]
The image receiving unit 150 of the second embodiment includes a receiving unit 152 that receives a radio signal representing an additional image input via the radio wave transmitting unit 142, and an electric signal that represents the radio signal received by the receiving unit 152 as an additional image. And an image signal converter 154 for converting the signal.
[0084]
FIG. 9 is a functional block diagram of the image transfer apparatus 300 according to the second embodiment. The difference from the first embodiment is that the additional image is transferred to the digital camera 10 in the form of a radio signal. That is, the image transfer apparatus 300 according to the second embodiment includes an image transfer unit 350 including a radio wave signal conversion unit 356 and an output amplifier 352.
[0085]
The radio signal conversion unit 356 converts the electric signal representing the additional image acquired by the image acquisition unit 340 into a radio signal such as a radio frequency band (for example, about several tens of MHz to several GHz), and outputs the radio signal to the output amplifier 352. Via the digital camera 10.
[0086]
When the additional image is stored in the storage medium 177 in the digital camera 10 using the image transfer apparatus 300 according to the second embodiment, for example, a sales clerk first installs a part of the digital camera 10 in the accommodation unit 330. The image transfer apparatus 300 transfers the radio signal representing the additional image converted by the radio signal conversion unit 356 to the digital camera 10 in a state where the digital camera 10 is mounted in the housing unit 330. Then, the digital camera 10 receives the radio signal representing the additional image transferred from the image transfer device 300 by the receiving unit 152 of the image receiving unit 150 provided inside the housing 300. Then, the digital camera 10 returns the received radio wave signal to an electrical signal by the image signal conversion unit 154 and stores it in the storage medium 177.
[0087]
As described above, also in the second embodiment, an advertisement image or the like can be stored in the storage medium 177 while the storage medium 177 is provided in the digital camera 10.
[0088]
FIG. 10 is a side view of the digital camera 10 according to the third embodiment. The second embodiment is different from the second embodiment in that the additional image transferred from the image transfer apparatus 300 is received in the form of an optical signal. That is, the digital camera 10 according to the third embodiment emits light via the housing 200 at substantially the same position as the side surface of the housing 200 where the radio wave transmitting unit 142 of the digital camera 10 according to the second embodiment is provided. It has a light transmission part 146 that transmits light. As long as this light transmission part 146 is a member which can permeate | transmit the optical signal showing an additional image, you may be comprised with what kind of member. For example, a light transmissive organic member (such as plastic) may be used, or an opening that penetrates the housing 200 may be used. In the case of an opening, the member is air. Note that this opening may be covered with a light-transmitting sealing member.
[0089]
FIG. 11 is a block diagram showing details of the activation control unit 130 and its peripheral part in the digital camera 10 according to the third embodiment. In the digital camera 10 of the third embodiment, the detection unit 132 detects whether or not an optical signal representing the additional image is input via the light transmission unit 146, so that the signal representing the additional image is converted into the digital camera. 10 is detected. Note that the detection unit 132 may be configured to detect a dedicated optical signal for transferring an optical signal representing the additional image to the digital camera 10.
[0090]
The image receiving unit 150 of the third embodiment includes a light receiving unit 156 that receives an optical signal representing an additional image input via the light transmitting unit 146, and an electrical signal that represents the optical signal received by the light receiving unit 156 as an additional image. And an image signal conversion unit 158 for converting into a signal.
[0091]
FIG. 12 is a functional block diagram of the image transfer apparatus 300 according to the third embodiment. The difference from the second embodiment is that the additional image is transferred to the digital camera 10 in the form of an optical signal. That is, the image transfer apparatus 300 according to the third embodiment includes an image transfer unit 350 including an optical signal conversion unit 358 and an output amplifier 352.
[0092]
The optical signal conversion unit 358 converts the electrical signal representing the additional image acquired by the image acquisition unit 340 into an optical signal such as infrared rays or a laser beam, and transfers the optical signal to the digital camera 10 via the output amplifier 352. .
[0093]
When the additional image is stored in the storage medium 177 in the digital camera 10 using the image transfer apparatus 300 according to the third embodiment, for example, a salesclerk first installs the digital camera 10 in the housing unit 330. The image transfer apparatus 300 transfers an optical signal representing an additional image converted by the optical signal conversion unit 358 to the digital camera 10 in a state where the digital camera 10 is mounted in the housing unit 330. Then, the digital camera 10 receives the optical signal representing the additional image transferred from the image transfer device 300 by the light receiving unit 156 of the image receiving unit 150 provided inside the housing 300. The digital camera 10 returns the received optical signal to an electrical signal by the image signal converter 158 and stores it in the storage medium 177.
[0094]
As described above, also in the third embodiment, an advertisement image or the like can be stored in the storage medium 177 while the storage medium 177 is provided in the digital camera 10.
[0095]
In the third embodiment, an optical connector or an optical cable may be used when transferring an optical signal between the image transfer apparatus 300 and the digital camera 10.
[0096]
As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. Various modifications or improvements can be added to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.
[0097]
【The invention's effect】
As described above, according to the present invention, an advertisement image or the like can be stored in a storage medium while the storage medium is provided in the image pickup apparatus.
[Brief description of the drawings]
1A and 1B are external views of a digital camera according to a first embodiment of an image pickup apparatus of the present invention, where FIG. 1A shows an image pickup surface, FIG. 1B shows an operation surface, and FIG.
FIG. 2 is a view showing main members housed in a housing of the digital camera according to the first embodiment.
FIG. 3 is a functional block diagram of the digital camera according to the first embodiment.
FIG. 4 is a block diagram showing details of an activation control unit and its peripheral part in the digital camera according to the first embodiment.
FIG. 5 is a diagram showing an embodiment of an image storage system of the present invention.
FIG. 6 is a functional block diagram of the image transfer apparatus according to the first embodiment.
FIG. 7 is a side view of a digital camera according to a second embodiment.
FIG. 8 is a block diagram showing details of an activation control unit and its peripheral part in the digital camera according to the second embodiment.
FIG. 9 is a functional block diagram of an image transfer apparatus according to the second embodiment.
FIG. 10 is a side view of a digital camera according to a third embodiment.
FIG. 11 is a block diagram showing details of an activation control unit and its peripheral part in a digital camera according to a third embodiment.
FIG. 12 is a functional block diagram of an image transfer apparatus according to a third embodiment.
[Explanation of symbols]
10 Digital camera
20 Imaging unit
40 Imaging control unit
60 processing units
62 Main CPU
100 display unit
110 Operation unit
120 Main power supply
122 Sub power supply
130 Start Control Unit
140 Input terminal
142 Radio wave transmission part
146 Light transmission part
150 Image receiver
152 Receiver
154 Image signal converter
156 Light receiver
158 Image signal converter
177 storage media
200 case
210 exterior paper
300 Image transfer device
330 housing
340 Image acquisition unit
350 Image transfer unit
352 output amplifier
356 Radio signal converter
358 Optical signal converter

Claims (17)

An image storage system comprising an image pickup device and an image transfer device, wherein an image is stored in a storage medium provided in the image pickup device,
The image transfer device has an image transfer unit that transfers the image to the image capturing device,
The image capturing apparatus, houses the storage medium inside the housing,
An image receiving unit disposed inside the housing for receiving the image transferred from the image transfer device;
A control unit for storing the image received by the image receiving unit in the storage medium,
A main power supply for supplying power to the imaging unit via a power supply circuit;
A sub power source for backing up the power of the timer of the imaging device;
Wherein said image from the image transfer apparatus to the image capturing apparatus have a <br/> a detector for detecting that it is transferred,
When the detection unit detects that the image is transferred, the power source circuit supplies power from the main power source to the storage medium and the image receiving unit when the power source circuit is activated. An image storage system that supplies power from the sub power source to the storage medium and the image receiving unit when not activated . The image capturing apparatus is:
A signal line switch for connecting either the imaging unit or the image receiving unit to a signal input terminal of the storage medium;
A switch for a control line that connects either the storage control unit that controls the storage medium or the main CPU to a control input terminal of the storage medium;
Further comprising
When detecting that the image is transferred, the detection unit connects the image receiving unit and the signal input terminal of the storage medium to the signal line switch, and connects the control line switch to the switch for the control line. When the storage control unit and the control input terminal of the storage medium are connected and the image transfer is not detected, the signal line switch is connected to the imaging unit and the storage medium. The image storage system according to claim 1, wherein a signal input terminal is connected, and the main CPU and the control input terminal of the storage medium are connected to the control line switch. The imaging apparatus further includes a printed circuit board electrical circuits are patterned on the inside of the housing,
The image storage system according to claim 1, wherein the storage medium is soldered onto the printed circuit board. The image transfer device further includes a storage unit capable of storing a part of the image capturing device,
The image receiving unit, the state in which part of the image pickup device is housed in the housing unit, an image storage according to any one of claims 1 to 3 receiving the image transferred from the image transfer apparatus system. The container has an output terminal that outputs an electrical signal representing the image,
The image capturing apparatus further includes an input terminal that can be fitted to the output terminal on one side surface of the housing corresponding to the output terminal in a state where a part of the image capturing apparatus is accommodated in the accommodating portion. ,
The image storage system according to claim 4, wherein the image receiving unit receives the electrical signal transferred via the output terminal and the input terminal. The image transfer unit transfers the electric signal representing the image is converted into radio signals have a radio signal converter for output, and the radio wave signal converted by the radio signal converting unit in the image capturing apparatus And
The image pickup apparatus is provided with a radio wave transmission unit that transmits radio waves via the casing on one side of the casing,
The image receiving unit
A receiving unit that receives the radio signal emitted from the radio signal conversion unit and transmitted through the radio wave transmission unit;
Image storage system according to any one of claims 1 to 4 and an image signal converting unit for converting said radio signal received by the receiving unit, the electrical signals representative of the image. The image transfer unit may transfer electrical signals representative of the image has an optical signal conversion section for converting into an optical signal and said optical signal converted by the optical signal conversion unit to said imaging apparatus And
The image pickup device is provided with a light transmission part that transmits light through the case on one side of the case,
The image receiving unit
A light receiving unit that receives the optical signal emitted from the optical signal conversion unit and transmitted through the light transmission unit;
Image storage system according to any one of claims 1 to 4 and an image signal converting unit that converts the optical signal received by the light receiving portion, the electrical signals representative of the image. Image and the main power supply for supplying power to the imaging unit via a power supply circuit, the imaging apparatus and a sub-power supply for backing up the power of the internal timer of the casing, the storage medium housed in the interior of the housing An image storage method for storing
A step that receive the image receiving member which is provided in the transferred the image said housing from an image transfer apparatus for transferring the image on the imaging device,
A step of storing the image received by the image receiving unit in the storage medium,
Detecting that the image has been transferred to the imaging device;
When it is detected that the image is transferred, when the power supply circuit is activated, power is supplied from the main power supply to the storage medium and the image receiving unit that receives the transferred image, and the power supply circuit Is not activated, supplying power from the sub power source to the storage medium and the image receiving unit;
An image storage method comprising: Storage control for connecting the image receiving unit and a signal input terminal of the storage medium to a signal line switch and controlling the storage medium to a control line switch when detecting that the image is transferred The image pickup unit and the signal input terminal of the storage medium are connected to the switch for the signal line when it is not detected that the image is being transferred. The image storage method according to claim 8, further comprising: connecting a main CPU and the control input terminal of the storage medium to the control line switch. An image capturing device for storing an image transferred from an image transfer device arranged outside the housing in a storage medium housed in the housing,
An imaging unit that captures a subject image;
An image receiving unit disposed inside the housing for receiving the image transferred from the image transfer device;
A control unit for storing the image received by the image receiving unit in the storage medium,
A main power supply for supplying power to the imaging unit via a power supply circuit;
A sub power source for backing up the power of the timer of the imaging device;
A detection unit for detecting that the image is transferred from the image transfer device to the image pickup device;
Have
When the detection unit detects that the image is transferred, the power source circuit supplies power from the main power source to the storage medium and the image receiving unit when the power source circuit is activated. An image capturing apparatus that supplies power from the sub power source to the storage medium and the image receiving unit when not activated . A signal line switch for connecting either the imaging unit or the image receiving unit to a signal input terminal of the storage medium;
A switch for a control line that connects either the storage control unit that controls the storage medium or the main CPU to a control input terminal of the storage medium;
Further comprising
When detecting that the image is transferred, the detection unit connects the image receiving unit and the signal input terminal of the storage medium to the signal line switch, and connects the control line switch to the switch for the control line. When the storage control unit and the control input terminal of the storage medium are connected and the image transfer is not detected, the signal line switch is connected to the imaging unit and the storage medium. The image pickup apparatus according to claim 10, wherein a signal input terminal is connected, and the main CPU and the control input terminal of the storage medium are connected to the control line switch. 12. The image receiving unit according to claim 10 or 11, wherein the image receiving unit receives the image transferred from the image transfer device in a state where a part of the image capturing device is stored in a storage unit provided in the image transfer device. The imaging apparatus described. In a state where a part of the image pickup device is accommodated in the accommodating portion, the output terminal is provided on one side surface of the casing corresponding to an output terminal that outputs an electric signal representing the image provided in the accommodating portion. further comprising an input terminal capable of fitting and,
The image capturing apparatus according to claim 12, wherein the image receiving unit receives the electrical signal transferred from the image transfer apparatus via the input terminal. On one side of the housing, a radio wave transmission unit that transmits radio waves through the housing is provided,
The image receiving unit is a radio wave signal obtained by converting an electric signal representing the image in the image transfer device, the receiving unit receiving the radio wave signal transmitted through the radio wave transmitting unit;
Imaging device according to any one of claims 10 to 12 and an image signal converting unit for converting said radio signal received by the receiving unit, the electrical signals representative of the image. The image capturing apparatus according to claim 14, wherein the reception unit is provided such that a reception surface faces the radio wave transmission unit. On one side surface of the casing, a light transmission portion that transmits light through the casing is provided,
The image receiving unit, and the an optical signal obtained by converting an electric signal representing the image in the image transfer device, a light receiving unit for receiving the optical signal transmitted through the light transmitting portion,
Imaging device according to any one of claims 10 to 12 and an image signal converting unit that converts the optical signal received by the light receiving portion, the electrical signals representative of the image. The image pickup device according to claim 16, wherein the light receiving unit is provided such that a light receiving surface faces the light transmitting unit.

Images