JP2008072675A - Imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve user friendliness and to improve user convenience and use in effectively utilizing IC tag information by displaying the IC tag information on a digital camera and acquiring an image of a photographic object and information of an IC tag in an associated manner with an operating method similar to originally photographing the photographic object. <P>SOLUTION: An imaging apparatus comprises a photographing means which photographs an object to acquire object image data; a recording means for recording the object image data; an IC tag recognizing means for recognizing tag information in an IC tag attached to the object; and a control means which creates coupling data by embedding the received tag information in an image information region of the object image data, and allows the recording means to record the coupling data. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an image pickup apparatus, and more particularly to an image pickup apparatus having an IC tag recognition device and a function of recognizing information on an IC tag attached to a subject.

In recent years, IC tags have attracted attention as an alternative to barcodes, and some products already have IC tags, especially those with embedded non-contact type IC tags. Techniques disclosed in Japanese Patent Laid-Open Nos. 2003-303328 and 2005-234871 are known.
In general, this type of non-contact IC tag includes an IC chip including a memory for recording information, an antenna connected to the IC chip and transmitting / receiving signals to / from an external device, and between the IC chip and the antenna. It consists of a conductor part that connects.
Such IC tags are embedded with detailed product information, and when accessed from an external device, unique tag information such as the product name and price of an article recorded on the IC chip is passed through the antenna via the antenna. The information read by the external device can be used for various purposes such as merchandise inventory management and distribution management.
JP 2003-303328 A JP 20052344871

However, in the past, in order to read and utilize the IC tag information, a dedicated reading device is required, which makes it difficult for general users to use, and even if the IC tag information is read, the product and its IC Because it is difficult to handle tag information in association with each other, it is difficult to say that the tag information is easy to use, and its use is limited.
Therefore, the present invention displays the IC tag information with a digital camera that is closer to the user without using a dedicated reading device, and also uses the same operation method as that used to originally shoot a photographed object (subject). The object is to improve usability by associating and acquiring information of an image and an IC tag, and to improve the convenience and use of the user in utilizing the IC tag information.

In order to solve the above-described problems, the invention described in claim 1 is directed to photographing means for photographing a subject to acquire subject image data, recording means for recording the subject image data, and an IC attached to the subject. IC tag recognizing means for recognizing tag information in the tag, and control means for creating combined data in which the received tag information is embedded in the image information area of the subject image data and recording the combined data on the recording means And an image forming apparatus.
According to a second aspect of the present invention, in the imaging apparatus according to the first aspect, the recording unit includes a data storage unit classified based on the tag information, and the control unit converts the combined data into the tag information. And an image pickup apparatus that records the data in the data storage means.
According to a third aspect of the present invention, there is provided a photographing means for photographing a subject to acquire subject image data, a recording means for recording the subject image data, and an IC for recognizing tag information in an IC tag attached to the subject. An image pickup apparatus comprising: a tag recognizing unit; and a control unit that generates combined data obtained by combining the tag information with the image of the subject represented by the subject image data, and records the combined data on the recording unit. To do.

According to a fourth aspect of the present invention, there is provided display means for displaying at least a subject, a lens barrel member provided with a plurality of lenses and focusing on at least the subject, recording means for recording the subject image data, and attached to the subject. IC tag recognition means for recognizing tag information in the IC tag, and control means for combining the tag information with the display of the subject on the display means after the lens barrel member has focused on the subject, An image pickup apparatus including
According to a fifth aspect of the present invention, there is provided photographing means for photographing a subject to acquire subject image data, IC tag recognition means for recognizing tag information in an IC tag attached to the subject, and the tag information based on the tag information. Changing means for changing shooting parameters of the shooting means, recording means for recording the subject image data, image compression means for compressing the subject image data, and recording for recording the compressed subject image data in the recording means And an imaging device comprising a control means.

  The present invention improves the usability of IC tag information and utilizes IC tag information by associating and acquiring information of an image and IC tag information by an operation method similar to that for photographing a subject (subject). User convenience and usage can be improved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic view of a digital camera which is an example of an imaging apparatus according to the present invention. FIG. 1 (a) is a top view of the camera, FIG. 1 (b) is a front view of the camera, and FIG. It is. FIG. 2 is a block diagram showing a digital camera as an example of the imaging apparatus of the present invention for each function.
First, the operation of a digital camera which is an example of the imaging apparatus of the present invention will be described with reference to FIGS.
1 and 2, a lens barrel unit (lens barrel means) 7 includes a zoom optical system 7-1 including a zoom lens 7-1a and a zoom motor 7-1b for capturing an optical image of a subject, a focus lens 7-2a, and a focus. Focus optical system 7-2 composed of motor 7-2b, diaphragm unit 7-3 composed of diaphragm 7-3a diaphragm 3b, mechanical shutter unit 7-4 composed of mechanical shutter motor 7-4b, each of these The motor driver 7-5 that drives the motor is included.

The operation key unit includes a power supply SW13 for turning on / off the battery power, a ZOOM / SW (WIDE) SW3, a ZOOM / SW (TELE) SW4, a self-timer / deletion SW / SW5, a MENU / SW / SW6, Up / Strobe SW / SW7, Right SW / SW8, DISPLAY / SW / SW9, Down / Macro SW / SW01, Left / Image Confirmation SW / SW11, OK / SW / SW12, Release Key SW1, It comprises a mode dial SW2 for instructing a shooting mode.
The motor driver 7-5 receives a signal from a CPU (Central Processing Unit) 104-3 in the digital still camera processor 104, which will be described later, based on an input to the remote control light receiving unit 6 or an operation key unit (SW1-SW13). Drive control is performed by a drive command.
A ROM (Read Only Memory) 108 stores a control program and control parameters written in a code readable by the CPU 104-3. By using a rewritable flash ROM for the ROM 108, the control program and control parameters can be changed, and the function can be easily updated.
When the power of the digital camera is turned on, the program is loaded into a main memory (not shown), and the CPU 104-3 controls the operation of each part of the apparatus according to the program and temporarily stores data necessary for the control. Recording is performed in the RAM 107 and a local SRAM (Static RAM) 104-4 in the digital still camera processor 104.

A CCD (Charge Coupled Device) 101 is a solid-state imaging device that photoelectrically converts an optical image as a photographing means, and a front-end IC 102 is a CDS (Correlated Double Sampling) 102-1, which performs double sampling for image noise removal. AGC (Automatic Gain Control) 102-2 that performs gain adjustment, A / D 102-3 that performs analog-digital signal conversion, a vertical synchronization signal (hereinafter referred to as VD) from the CCD1 control unit 104-1 in the digital still camera processor 104, A CCD 101 that is supplied with a horizontal synchronization signal (HD) and controlled by the CPU 104-3, and a TG (Timing Generator) 102-4 that generates a drive timing signal for the front-end IC 102 are provided.
The digital still camera processor 104 performs white balance setting and gamma setting on the output data of the front-end IC 102, and also converts the luminance data and color difference data by the CCD1 control unit 104-1 for supplying the VD signal and HD signal described above, and filtering processing. CCD2 control unit 104-2 for performing conversion, CPU (control means) 104-3 for controlling the operation of each unit described above, local RAM 104-4 for temporarily storing data necessary for the above control, personal computer, etc. Universal Serial Bus (USB) control unit 104-5 that performs USB communication with other external devices, serial control unit 104-6 that performs serial communication, JPEG codec unit 104-7 that performs JPEG compression / decompression, and complements the size of image data The RESIZE unit 104-8 that is enlarged or reduced by processing, and image data TV signal display unit 104-9 for converting the video signal to a video signal for display on an external display device such as a liquid crystal monitor or TV, a memory card for recording captured image data, and a general-purpose PCMCIA (Personal Computer Memory Card International Association) ) A memory card controller 104-10 for controlling a card, a CF (Compact Flash), a GPS card compatible with an SD (Secure Digital) card, and the like.

The SDRAM 103 temporarily records image data when the digital still camera processor 104 performs various processes on the image data. Data to be recorded is captured from the CCD 101 via the front-end IC 102, for example, and RAW-RGB image data in which white balance setting and gamma setting are performed by the CCD1 signal processing unit 104-1, or the CCD2 control unit 104. 2 is the YUV image data after the luminance data / color difference data conversion is performed, the JPEG image data subjected to JPEG compression by the JPEG codec unit 104-7, and the like.
The memory card slot 121 is a slot for mounting a removable memory card, a GPS card, or the like. The built-in memory 120 is a memory that allows recorded image data to be recorded even when no memory card is inserted in the memory slot 121 described above.

The LCD driver 111 is a drive circuit that controls the LCD monitor 10 to be described later, and has a function of converting the video signal output from the TV signal display unit 104-9 into a signal for display on the LCD monitor 10. .
The LCD monitor 10 is a monitor that displays a preview of a photographed image, for example. The LCD monitor 10 monitors the state of a subject before photographing, confirms a photographed image, and records image data recorded in a memory card or the built-in memory 120 described above. Used to display
The video AMP 118 is an amplifier for converting the impedance of the video signal output from the TV signal display block 104-9 to 75Ω, and the video jack 119 is a jack for connecting to an external display device such as a TV. The USB connector 122 is a connector for performing serial connection with an external device such as a personal computer.
The serial driver circuit 123-1 is a circuit for voltage-converting the output signal of the serial unit 104-6 described above in order to perform serial communication with an external device such as a personal computer. The RS-232C connector is a serial connection. It is a connector for.

The SUB-CPU 109 is a CPU in which ROM and RAM are built in one chip, and is output from the above-described CPU 104-3 as operation information of the operation key unit (SW1-13) and the remote control light receiving unit 6 as user operation information. The camera state is converted into control signals for a sub LCD 1, AF LED 8, strobe LED 9, and buzzer 113, which will be described later, and output.
The sub LCD 1 is a display unit for displaying, for example, the number of images that can be shot and shooting conditions such as a shooting mode (bulb mode). The sub LCD driver 111 is based on the output signal of the SUB-CPU 109 described above. This is a drive circuit for driving the LCD 1.
The AF LED 8 is an LED for displaying an in-focus state at the time of photographing, and the strobe LED 9 is an LED for representing a strobe charging state.
The AF LED 8 and the strobe LED 9 may be used for other display applications such as indicating that the memory card is being accessed.

The operation key unit (SW1-13) is a key circuit operated by the user, and the remote control light receiving unit 6 is a signal reception unit of the remote control transmitter operated by the user.
The sound recording unit 115 includes a microphone 115-3 for inputting a sound signal by a user, a microphone AMP 115-2 for amplifying the input sound signal, and an audio AMP 116-2 for amplifying the amplified sound signal and driving a speaker. And a speaker 116-3 for outputting an audio signal.
The direction sensor unit 117 includes an acceleration / gyro sensor 117-2 that detects and outputs a direction and acceleration, and an A / D conversion circuit 117-1 that converts an analog signal output from the sensor into a digital signal.
An IC tag recognition unit (IC tag recognition unit) 301 is a receiving unit that receives information from an IC tag and a device that analyzes the information and transmits the information to the digital still camera processor 104, and analyzes the information from the IC tag. And an antenna 17 and a modem circuit receiver.

Hereinafter, an aspect in which the imaging apparatus according to the present invention reads and uses an IC card attached to a photographed object will be described in detail.
[Example 1]
A first embodiment of the present invention will be described.
First, IC tag data is acquired by an IC tag recognition unit 301 from an IC tag embedded in a photographed object (subject) that is within the photographing range of a digital still camera at the time of photographing the subject, and information is recognized.
Here, the IC tag is a non-contact IC tag. The non-contact IC tag is an IC chip including a memory for recording information, an antenna connected to the IC chip and transmitting a signal in a non-contact manner to an external device, and a conductor portion connecting the IC chip and the antenna. It is made up of.
The IC tag recognition unit 301 reads the information in the IC tag (IC tag information) through the antenna and the modem circuit.
Although all of the acquired tag information may be embedded, the user may determine (select) necessary information.

Data acquired by the IC tag recognition unit 301 is transferred to the digital still camera processor 104. The CPU 104-3 searches and extracts only the information specified by the user from the tag information in the IC tag data sent from the IC tag recognition unit 301 (not required when all tag information is used).
The CPU 104-3 creates combined data in which these data (specified information required by the user) are embedded in a part of the data format of the photographed object image data that has been simultaneously photographed and processed, and the built-in memory 120 or Recording is performed on a memory card (recording unit) inserted in the memory card slot 121.
Thereby, tag information of all the photographed objects within the photographing range can be easily recorded in association with the photographed object simply by photographing the photographed object.
Here, a method in which the user determines (selects) tag information to be embedded in the image information area of the photographed object image data will be described. Information required by the user may be determined (selected) in advance and recorded in the camera, or may be arbitrarily determined (selected) by the user during shooting.

First, a case will be described in which designated tag information required by the user is determined (selected) in advance before shooting.
When determining (selecting) the designated tag information to be embedded in the photographed object image in advance before shooting, the user determines (selected) the designated tag information necessary from the list of designated tag information.
Here, the list of designated tag information may be created by, for example, recording a list of designated tag information already created by the user on the camera by transferring it to the camera using an external device such as a PC. However, it may be created by specifying the type of designated tag information to be embedded in the photographed object image from the camera photographing mode and the kind of photographed object assumed in this photographing mode, and causing the camera to directly record the designated tag information. .
Examples of the camera mode include a night view mode, a close-up mode, an underwater mode, a sports mode, an auction mode, and an indoor mode. For example, in the night view mode, there are streetlights, illuminated buildings, flowers and insects in the close-up mode, small fish and sharks in the underwater mode, and small fishes and fishes in the sports mode. There are sprinters and balls in ball games, clothes and toys in the auction mode, furniture such as CD jackets and shelves, and people and pets (animals) in the indoor mode.

Next, a case where the user arbitrarily determines (selects) designated tag information at the time of shooting will be described.
In the camera in which the photographed image is displayed on the LCD monitor 10 as a preview image, the designated tag information acquired regarding the preview image is displayed in correspondence with the preview image display on the LCD monitor 10. The designated tag information at this time may be displayed on the LCD monitor so as to be superimposed on the preview image, or may be displayed on the sub LCD 1 as character information.
Then, the user arbitrarily determines (selects) necessary designated tag information from the displayed designated tag information.
The list of designated tag information is not limited to the list obtained by acquisition / recording, but may be any list that allows the user operating the camera to determine (select) the designated tag information.
The determination (selection) of designated tag information is the same for the following embodiments.

By the way, a method of embedding tag information in the photographed object image data will be described. As an example, a method of recording in an image information area of image data, for example, a tag area of Exif format (an area in which image information such as an image size is recorded) can be considered. Specifically, the information (hereinafter, designated tag information) designated by the user is recorded in the manufacturer note area in the Exif format (the area in the Exif format where the recording contents can be determined by the manufacturer). .
In the present embodiment, embedding the information in the received IC tag data as a part of the information of the photographed image data is a case of embedding according to a unique format in addition to recording in the manufacturer note area of the Exif format. These embedding methods can be freely selected.
That is, it is sufficient if it is an area where the designated tag information can be recorded, and it is not limited to the Exif format or a unique format. Further, it is assumed that which information is selected from the tag information can be freely selected.

FIG. 3 is a flowchart showing the flow of processing of this embodiment. This is a flowchart when the user selects (determines) tag information in advance or at the time of shooting. When the user presses the release key SW1 to make a shooting request (Yes in S100), the IC tag recognizing unit 301 acquires tag information of a shot within the shooting range (S101). The CPU 104 searches and extracts information necessary for the user from the information acquired by the IC tag recognition unit 301 (S102). Subsequently, the photographed object within the photographing range is photographed, and photographed object image data is captured (S103). The CPU 104 combines the photographed object image data and the designated tag information to create combined data (S104). Finally, the CPU 104 records the combined data in the built-in memory 120 (recording unit) or the memory card.
With the configuration described above, the convenience of the user can be improved and the use of the IC tag can be expanded.

[Example 2]
A second embodiment of the present invention will be described.
First, when photographing a subject, the IC tag recognition unit 301 acquires (receives) IC tag data recorded on an IC tag embedded in a photographed object (subject) within the photographing range, and recognizes information. . Then, only designated information (designated tag information) required by the user is searched and extracted by the CPU 104-3 of the digital still camera processor 104, and an image-processed photographed image is combined as shown in FIG. The CPU 104-3 records the composite data on the internal memory 120 or the memory card inserted in the memory card slot unit 121.
An example in which IC tag information is embedded and recorded in a photographed object image will be described with reference to FIG.
In FIG. 8, IC tags are attached to umbrellas, pottery, and faxes. These three photographed objects are photographed as one photographed image, and the IC tag is read as described above to acquire tag information.
All of the acquired information may be embedded in the image, but the user may determine (select) necessary information.

Hereinafter, this point will be described.
When all of the acquired information (in the example of FIG. 8, all of tag information related to umbrellas, pottery, and FAX) is used as information to be combined with an image, this information is combined with the corresponding position of the captured image.
When the user determines (selects) tag information to be combined with the photographed image, the user determines (selects) necessary information from all the tag information.
The method for determining (selecting) information to be combined is the same as the method for determining (selecting) tag information to be embedded in the image data of the first embodiment.
Displaying tag information to be displayed on the image at a position corresponding to the photographed object image will be described. As described above, the tag information to be displayed is either all acquired tag information or designated tag information determined (selected) by the user in advance or at the time of shooting.
Here, with respect to the photographed image, its edge is recognized and used as a reference, and a position away from the reference position by a predetermined distance (for example, several millimeters on the LCD monitor 10) may be a position corresponding to the photographed image.

Further, as a method for the user to determine the position corresponding to the photographed image when previewing the photographed image, for example, a quadrangle consisting of a dotted line indicating the tag information display area on the LCD monitor 10 is superimposed on the preview image and displayed. The display position of the tag information may be determined with the OK button by moving the square on the LCD monitor 10 by operating the up / down / left / right buttons (SW6, SW7, SW8, SW11).
This makes it possible to easily record the tag information of all the photographed objects as an image file simply by photographing. Furthermore, the tag information display method and which information is selected are not limited to those shown in FIG. 8, but can be freely selected.

FIG. 4 is a flowchart showing the flow of processing of this embodiment. This is a flowchart when the user selects (determines) tag information in advance or at the time of shooting. When the user presses the release key SW1 to make a shooting request (Yes in S200), the IC tag recognizing unit 301 acquires tag information of a shot within the shooting range (S201). The CPU 104-3 searches for and extracts designated tag information from the information acquired by the IC tag recognition unit 301 (S202). Subsequently, the photographed object within the photographing range is photographed, and photographed object image data is captured (S203). The CPU 104-3 synthesizes the designated tag information with the photographed object image and creates synthesized data (S204). Finally, the CPU 104 records the composite data in the built-in memory 120 or the memory card.
In addition, when acquiring specified tag information from each photographed object as described above, depending on the arrangement of the photographed object, such as when a plurality of different photographed objects are close to each other, the acquired tag information and the photographed image may differ. Can occur.
In such a case, for example, tag information and a photographed image photographed object image) are superimposed and displayed on the LCD monitor 10 at the time of photographing, and the user selects and corrects an IC tag that differs from the photographed image (character information). The tag information and the captured image can be associated with each other correctly.
Further, as will be described later, it can be automatically corrected.
With the configuration described above, the convenience of the user can be improved and the use of the IC tag can be expanded.

[Example 3]
Next, a third embodiment of the present invention will be described.
First, when the user enters a confirmation (viewable) mode of an image taken from the LCD monitor 10 or an EVF (Electric View Finer) (not shown), the LCD monitor (display means) 10 and the EVF (display means) The image to be taken can be confirmed. In this state, when the release key SW1 of the operation key unit (SW1-13) is pressed, focusing is performed by the lens barrel unit 7 to focus on the photographed object.
Get tag information triggered by focusing on the object. In other words, when the release key is pressed to focus, the IC tag recognition unit 301 acquires (receives) the tag information of the photographed object from the IC tag and recognizes the information. As described above, the CPU 104-3 of the digital still camera processor 104 searches only the information designated as necessary by the user, and displays it on the LCD monitor 10 and the viewfinder together with the image as shown in FIG.
As a method for displaying the tag information and the image together in FIG. 9, the method for obtaining, determining (selecting), and displaying the tag information in FIG. 8 described above may be used.
As a result, various information on the photographed object can be understood at a glance by simply displaying the tag information on the photographed object to be viewed with the digital camera.
Furthermore, the tag information display method and which information is selected are not limited to the example shown in FIG. 9 and can be freely selected.

FIG. 5 shows a flowchart of the above embodiment. This is a flowchart when the user selects (determines) tag information in advance or at the time of shooting.
When the user focuses on the photographed object with the lens barrel unit 7 (YES in S300), the tag information of the photographed object within the focused photographing range is acquired (S301). The CPU 104-3 searches for and extracts designated tag information from the information acquired by the IC tag recognition unit 301 (S302), and the CPU 104-3 combines the tag information with the display of the photographed object (S303). Tag information is displayed on the viewfinder (S304).

Here, a method of automatically correcting an error such as a difference between the acquired tag information and the photographed object that occurs when a plurality of different photographed objects approach each other will be described.
When focusing is performed with the lens barrel unit 7 and the photographed object displayed on the LCD monitor 10 of the camera and the content displayed as tag information of the photographed object are inconsistent, the combined focus is temporarily set. After canceling, the photographed object for which tag information is to be acquired is focused again, and the IC tag recognition unit 301 of the photographed object obtains (receives) data from the IC tag to recognize the information. That is, release key SW1 is once released, release key SW1 is pressed again to focus, data is acquired (received) from the IC tag, and tag information is recognized. At this time, the tag information and the photographed object are superimposed and displayed on the LCD monitor 10, and the user visually confirms that the photographed object and the data are correctly associated with the IC tag. In this way, tag information that is inconsistent with the photographed object is corrected using the focus on the photographed object as a trigger (further correct tag information is acquired).
Note that the automatic correction of tag information at the time of focusing on a plurality of captured objects is not limited to the above-described example, and any tag information that can re-acquire tag information of the captured object can be used.
With the configuration described above, the convenience of the user can be improved and the use of the IC tag can be expanded.

[Example 4]
A fourth embodiment of the present invention will be described.
First, at the time of photographing, tag information of a photographed object within the photographing range is acquired by the IC tag recognition unit 301, and the tag information is recognized. Then, only the information designated by the user is retrieved and extracted by the CPU 104-3 of the digital camera processor 104, and recorded in a part of the data format of the photographed image subjected to image processing.
Then, the data is automatically classified and recorded in a recording folder (data storage means) for each classification created in advance by the information of the tag information on the memory card inserted into the memory card slot 121.

This classification will be described.
For this classification, tag information recorded in the manufacturer note area in the Exif format described above can be acquired, and this acquired information (and part of the acquired information) can be used as a classification. For example, tag information of a photographed image (or / and individual photographed object) is recorded in a manufacturer note area in the Exif format, and all (or a part) of tag information is acquired from this area and classified and used. Can do.
The acquired tag information can be edited and displayed (sorted) by an external device such as a PC (or a camera liquid crystal monitor).
Operations such as editing can be performed manually by the user, or may be automatically performed by a program recorded in advance by a camera, a program recorded in an external device, or the like.
Later (regardless of the time of shooting), the above-described combined file (file in which tag information is embedded in the shot image data) is classified by the user according to the information of the IC tag (eg, outerwear, skirt, It is possible to automatically divide a folder like pants.
In this case, the operation to be automatically divided can also be performed by a program recorded in the camera in advance, a program recorded in the external device, or the like.

FIG. 6 is a flowchart showing the flow of the above embodiment. This is a flowchart when the user selects (determines) tag information in advance or at the time of shooting.
When the user makes a shooting request by pressing the release key SW1 (Yes in S400), the IC tag recognition unit 301 acquires tag information of a photographed object that is in the shooting range (S401). The CPU 104-3 searches and extracts designated tag information from the information acquired by the IC tag recognition unit 301 (S402). Subsequently, the photographed object within the photographing range is photographed, and photographed object image data is captured (S403). The CPU 104-3 combines the designated tag information with the photographed object image data to create a combined file (S404). Finally, the CPU 104-3 classifies the files based on the tag information in the combined file, and records the combined file in the built-in memory 120 or the memory card (S405).
In this way, user convenience can be improved.

[Example 5]
A fifth embodiment of the present invention will be described.
First, the tag information of a photographed object that is within the photographing range at the time of photographing with the camera is acquired by the IC tag recognition unit 301 to recognize the information. Then, the CPU 104-3 in the digital camera processor 104 searches and extracts only the information specified by the user, and changes the predetermined image parameter based on the information.
The shooting parameters indicate items that affect shooting, such as white balance, edge enhancement, EV value, Gamba value, color balance, and the like. Then, the image is taken with the parameters, compressed by the JPEG codec unit 104-7 of the digital camera processor unit 104, and recorded as a JPEG file on the memory card inserted in the memory card slot 121.

For example, a case where a red apple is used as a photographed object and the photographed object has tag information will be described.
For digital still cameras, for example, when the color is red, the color balance is a parameter value that enhances red and emphasizes vividness, and when the object is fruit, the edge enhancement is weakened and the fruit is delicious. Like parameter values such as taking a picture to show, parameter data associated with a photographed object is registered for each image parameter. In this case, the tag information of the apple that is the photographed object is acquired by the IC tag recognition unit, and the tag information of the apple is recognized.
That is, the specified tag information is acquired that the photographed object is an apple and the photographed object is red, and based on this information, the photographing parameters are set using the data of each parameter associated with the photographed object by the digital still camera. change.
In the above red apple example, based on the tag information of the acquired tag information apple, red, change the color balance parameter to increase the color balance red, and change the shooting parameters to weaken the edge To do.

The flow of the above processing is shown in the flowchart of FIG. This is a flowchart when the user selects (determines) tag information in advance or at the time of shooting.
When the user presses the release key SW1 to make a photographing request (Yes in S500), the IC tag recognition unit 301 acquires tag information of a photographed object within the photographing range (S501). The CPU 104-3 searches and extracts designated tag information from the information acquired by the IC tag recognition unit 301 (S502).
Subsequently, based on the extracted information, the shooting parameter is changed to the shooting parameter suitable for the shooting object (S503), the shooting object within the shooting range is shot along with the shooting parameter, and the shooting object image data is captured. (S504). The JPEG CODEC unit 104-3 compresses the photographed object image data into a JPEG file (S505), and the CPU 104-3 as a recording control unit records it in the built-in memory 120 or the memory card (S506).
By doing in this way, it is possible to shoot with optimum image parameters depending on the object to be photographed without performing troublesome operations such as mode switching.
That is, since the shooting parameters matching the object can be automatically changed based on the read tag information, there is an effect that the user's operability can be improved and an optimum image can be easily taken. .
In addition, the present invention is an invention in which shooting parameters are changed based on tag information of a shot object, and needless to say, the timing to change, parameters to be changed, and the like are not limited to the above example.

1 is a schematic view of a digital camera that is an example of an imaging apparatus of the present invention. FIG. 3 is a block diagram illustrating a digital camera, which is an example of an imaging apparatus of the present invention, for each function. The flowchart which showed the flow of the process of 1st Example. The flowchart which showed the flow of the process of 2nd Example. The flowchart which showed the flow of the process of 3rd Example. The flowchart which showed the flow of the process of 4th Example. The flowchart which showed the flow of the process of 5th Example. The figure which shows the example which embeds and records IC tag data information in a to-be-photographed object image. The figure which shows the example which displays tag information and an imaging | photography thing together.

Explanation of symbols

  7 lens barrel unit, 6 remote control light receiving unit, SW1 to SW13 operation unit key unit, 104 digital still camera processor, 102 front-end IC, 101 CCD, 102-1 CDS, 102-2 AGC, 104-4 Local SRAM, 104- 5 USB block, 104-7 JPEG CODEC, 103 SDRAM, 121 card slot, 120 built-in memory, 117 LCD driver, 10 LCD monitor, 301 IC tag recognition unit, 104-3 CPU

Claims (5)

Photographing means for photographing a subject and obtaining subject image data;
Recording means for recording the subject image data;
IC tag recognition means for recognizing tag information in an IC tag attached to the subject;
An imaging apparatus comprising: control means for creating combined data in which the received tag information is embedded in an image information area of the subject image data, and recording the combined data on the recording means. The imaging device according to claim 1,
The recording means includes data storage means classified based on the tag information,
The control unit causes the data storage unit to record the combined data based on the tag information. Photographing means for photographing a subject and obtaining subject image data;
Recording means for recording the subject image data;
IC tag recognition means for recognizing tag information in an IC tag attached to the subject;
Control means for creating synthesized data obtained by synthesizing the tag information with the image of the subject represented by the subject image data, and causing the recording means to record the synthesized data;
An imaging apparatus comprising: Display means for displaying at least the subject;
A lens barrel member that includes a plurality of lenses and focuses at least on the subject;
Recording means for recording the subject image data;
IC tag recognition means for recognizing tag information in an IC tag attached to the subject;
Control means for combining the tag information with the display of the subject on the display means after the lens barrel member focuses on the subject;
An imaging apparatus comprising: Photographing means for photographing a subject and obtaining subject image data;
IC tag recognition means for recognizing tag information in an IC tag attached to the subject;
Changing means for changing the shooting parameters of the shooting means based on the tag information;
Recording means for recording the subject image data;
Image compression means for compressing the subject image data;
An image pickup apparatus comprising: a recording control unit that causes the recording unit to record the compressed subject image data.

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