JP2004304730A - Digital camera and image processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a digital camera which eliminates waste as much as possible in the digital camera which transmits image data. <P>SOLUTION: The digital camera is provided with a communication means for transmitting the photographed image data to an external device and a deletion means capable of deleting the image data photographed at the end by a specific operation within a prescribed period after photographing, and holds the transmission of the image data during the prescribed period when the image data can be deleted by a deletion means, then transmits the image data to the external device after the end of the prescribed period. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
[Industrial application fields]
The present invention relates to a digital camera and an image processing apparatus, and more particularly to a digital camera and an image processing apparatus that handle image data.
[0002]
[Prior art]
There has been proposed a digital camera which has a communication function and transmits image data captured by a digital camera to an external server computer or the like without storing it in the memory of the camera and stores it in the memory of the external server computer. Yes. As a result, a minimum amount of memory is prepared in the camera, and a large amount of images can be taken without worrying about the memory.
[0003]
[Problems to be solved by the invention]
However, if image data is transmitted immediately after shooting, even failed image data is transmitted. To delete it, it is necessary to send a deletion signal, which may increase communication costs. It can also be a cause of congestion in communication traffic.
[0004]
The present invention provides a digital camera that eliminates waste as much as possible in a digital camera that transmits image data.
[0005]
[Means for Solving the Problems]
According to the first aspect of the present invention, in the digital camera, a communication unit for transmitting captured image data to an external device, and a deletion unit that can delete the last captured image data for a predetermined period after the capturing by a specific operation. The communication unit waits for transmission of image data for a predetermined period that can be deleted by the deletion unit, and transmits the image data to an external device after the predetermined period ends. As a result, image data that does not need to be saved is not sent unnecessarily, and the influence on communication costs and communication traffic is reduced.
[0006]
According to a second aspect of the present invention, the digital camera according to the first aspect is provided with a display unit, and the last photographed image data is displayed on the display unit during the predetermined period.
[0007]
According to a third aspect of the present invention, in the digital camera according to the second aspect, the display means is configured to perform a display prompting a deletion operation together with the last photographed image data during the predetermined period.
[0008]
According to a fourth aspect of the present invention, in the digital camera according to the first aspect, the image data transmitted to the external device by the communication means is RAW image data.
[0009]
According to a fifth aspect of the present invention, in the image processing apparatus, a communication unit that transmits captured image data to an external device, an image processing unit that performs optimization processing on the image data, and the communication unit are used. Control means for instructing image data to be transmitted to the external apparatus, and image data instructed to be transmitted to the external apparatus by the instruction means to be optimized by the image processing means. And a control means. As a result, the optimization process is performed only on the image data to be transmitted, so the burden is reduced. Further, since the image data that has not been optimized is optimized when the image data is transmitted, the latest optimization process is performed.
[0010]
According to a sixth aspect of the present invention, in the image processing apparatus according to the fifth aspect, the instruction unit is configured to instruct image data for which a print order has been placed.
According to a seventh aspect of the present invention, in the image processing apparatus according to the fifth aspect of the present invention, the image processing apparatus further includes an acquisition unit that acquires captured camera information, and the optimization process is optimized for image data based on the camera information. It was set as the structure which performs a conversion process.
[0011]
According to an eighth aspect of the present invention, in the image processing device according to the seventh aspect, the camera information is aberration information of the photographing lens.
According to a ninth aspect of the present invention, in the image processing apparatus according to the fifth aspect, the image data is RAW image data.
[0012]
In the invention according to claim 10, in the image processing device, a communication unit that transmits captured image data to an external device, an image processing unit that performs optimization processing on the image data, and the communication unit are used. The image processing unit performs an optimization process on the image data excluding the image data to be transmitted to the external apparatus and the image data excluding the image data instructed to be transmitted to the external apparatus by the instruction unit. And a control means for controlling so as to be applied.
[0013]
According to an eleventh aspect of the present invention, in the image processing apparatus according to the tenth aspect, the external apparatus includes a second image processing unit that performs an optimization process on the image data. As a result, the image data to be transmitted to the external device can be divided and processed such that the external device performs optimization processing, and the image data not to be transmitted to the external device is subjected to optimization processing by the image processing device.
[0014]
In the invention according to claim 12, in the image processing apparatus, a receiving means for receiving image data from a digital camera, an image processing means for performing optimization processing on the image data received by the receiving means, and the image processing And a transmission means for automatically transmitting the image data subjected to the optimization process to the digital camera. This realizes usability as if the optimization process was performed in the digital camera for the user of the digital camera.
[0015]
According to a thirteenth aspect of the present invention, in the image processing apparatus according to the twelfth aspect of the present invention, the image processing apparatus includes an acquisition unit that acquires captured camera information, and the optimization process is optimized for image data based on the camera information. It was set as the structure which performs a conversion process.
[0016]
According to a fourteenth aspect of the present invention, in the image processing apparatus according to the thirteenth aspect, the camera information is aberration information of the photographing lens.
According to a fifteenth aspect of the present invention, in the image processing apparatus according to the twelfth aspect, the image data is RAW image data.
[0017]
According to a sixteenth aspect of the present invention, in the image processing apparatus according to the twelfth aspect of the present invention, the image processing apparatus includes an identification unit that identifies a file format of the received image data. When the identification unit detects that the image data is RAW image data, The configuration is such that optimization processing is performed after pixel interpolation processing.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
FIG. 1 is a functional block diagram showing an overview of the camera system of the first embodiment. In FIG. 1, the camera system of the first embodiment includes a mobile phone 1 with a camera, a provider 2, an authentication server 3, an image storage server 4, and a print server 5.
[0019]
The camera-equipped cellular phone 1 is a cellular phone in which a digital camera function is added to the cellular phone. The camera-equipped mobile phone 1 includes a mail function as an Internet terminal, a WEB browsing function, and the like in addition to a call function as a mobile phone. Provider 2 is an Internet service provider operated by a mobile phone carrier. The authentication server 3 is a computer for authenticating whether or not the user is a registered user from user information transmitted from the camera-equipped mobile phone 1. The authentication server 3 stores the latest version of the image optimization program. The image storage server 4 is a computer that stores image data captured by the camera-equipped mobile phone 1. The print server 5 is a computer that performs processing for printing image data captured by the camera-equipped mobile phone 1. The print server 5 is installed in a minilab. The print server 5 holds a program for optimizing the image quality of image data taken by the camera-equipped mobile phone 1 or the like.
[0020]
The print server 5 can obtain the latest image optimization program by accessing the authentication server 3. For example, when the latest compression method is developed, the image data can be compressed by the latest compression method by changing the image processing program stored in the print server 5. Therefore, even if the camera itself has a function that cannot be improved by an IC image processing circuit, the function can be improved. In addition, the digital camera itself can cope with various image processing that could not be realized due to problems such as program capacity and CPU load. The printer 6 is connected to the print server 5 and prints image data according to a command from the print server 5. The printer 6 may be an ink jet system, a laser system, or a system that optically prints on silver halide photographic paper. The personal computer 7 is a computer terminal used by a user.
[0021]
The personal computer 7 can communicate with the authentication server 3 and the print server 5 via the provider 8. The personal computer 7 holds a program for optimizing the image quality of the image data taken by the camera-equipped mobile phone 1 or the like, similar to the print server 5. The personal computer 7 is connected to the camera-equipped mobile phone 1 and receives image data such as RAW image data captured by the camera-equipped mobile phone 1. The received RAW image data and compressed image data can be optimized by an image optimization program as with the print server 5. Identification data is attached to the image data optimized by this program to prevent the print server 5 from executing the same optimization program again. However, the optimization program may be updated. As will be described later, the print server 5 is always updated to the latest version of the program. When the optimization program of the personal computer 7 is older than the version of the optimization program of the print server 5, the print server 5 adds only the difference image processing to the image data optimized by the personal computer 7. . The provider 8 is an Internet service provider operated by an operator different from the mobile phone operator used by the personal computer user.
[0022]
The configuration of main devices will be specifically described below.
First, the camera-equipped mobile phone 1 will be described. FIG. 2 is a block diagram showing the configuration of the camera-equipped mobile phone 1.
[0023]
As shown in FIG. 2, the camera-equipped mobile phone 1 includes an image sensor 11, an image processing circuit 12, a CPU 13, a built-in memory 14, a card slot 15, a shutter button 16, a monitor 17, a communication circuit 18, and the like. Naturally, the camera-equipped mobile phone 1 includes not only the above-described circuits and operation buttons, but also circuits and operation buttons necessary for using the call function, mail function, Internet function, etc., which will be described. Is omitted.
[0024]
The image sensor 11 is an element for imaging a subject and is, for example, a CCD (Charge Coupled Device) having about 2 million pixels. In addition, the image sensor 11 can perform thinning readout from 2 million pixels and output image data of about 350,000 pixels. The image processing circuit 12 is a circuit that performs image processing such as interpolation, thinning, and compression of image data. The image processing circuit 12 is a circuit that is optimally designed for processing image data of about 350,000 pixels read out from the CCD. The CPU 13 is a circuit that controls the camera function, communication function, and the like of the camera-equipped mobile phone 1.
[0025]
The built-in memory 14 is a non-volatile semiconductor memory and stores a program for executing the camera function, the communication function, and the like of the camera-equipped mobile phone 1. The card slot 15 is for mounting a memory card in the slot and writing data such as image data in the mounted memory card. The shutter button 16 is a button for the user to operate when shooting is started. A dedicated button for starting shooting may be provided, or an operation button for executing another function may be used. The monitor 17 is for displaying image data and the like, and uses, for example, a liquid crystal display. The communication circuit 18 is a circuit for transmitting data such as image data to the outside.
[0026]
Next, the authentication server 3 will be described. FIG. 3 is a block diagram showing the configuration of the authentication server 3.
As shown in FIG. 3, the authentication server 3 includes a CPU 31, a customer database 32, a laboratory database 33, a program storage unit 36, a communication circuit 35, and the like.
[0027]
The CPU 31 is a circuit for executing an authentication program or the like of the authentication server 3. The customer database 32 is a database in which information on users such as camera-equipped mobile phones is registered. The laboratory database 33 is a database in which information on a print laboratory that performs printing is registered. The program storage unit 34 includes a program for authenticating the user. The program storage unit 34 always stores the latest image optimization program. The communication circuit 35 is a circuit for communicating data such as image data with other devices using a communication network such as the Internet.
[0028]
Next, the image storage server 4 will be described. FIG. 4 is a block diagram showing the configuration of the image storage server 4.
As shown in FIG. 4, the image storage server 4 includes a CPU 41, an image storage unit 42, a communication circuit 43, and the like.
[0029]
The CPU 41 is a circuit for executing an image storage program of the image storage server 4 and the like. The image storage unit 42 is a memory that stores user image data. The communication circuit 43 is a circuit for communicating data such as image data with other devices using a communication network such as the Internet.
[0030]
Next, the print server 5 will be described. FIG. 5 is a block diagram showing the configuration of the print server 5.
As shown in FIG. 5, the print server 5 includes a CPU 51, a print program storage unit 52, an image optimization program storage unit 53, a communication circuit 54, a hard disk device 55, and the like.
[0031]
The CPU 51 is a program for executing a print program, an image optimization program, and the like of the print server 5. The print program storage unit 52 is a memory that stores a program that realizes printing of image data by the printer 6. The image optimization program storage unit 53 is a memory that stores a program for optimizing the image quality of image data. The communication circuit 54 is a circuit for communicating data such as image data with other devices using a communication network such as the Internet. The hard disk device 55 is a memory that temporarily stores received image data.
[0032]
Next, an outline of control executed by the system of this embodiment will be described.
First, the camera-equipped mobile phone 1 transmits authentication data before transmitting image data using an image transfer program stored therein. The authentication data 3 transmitted from the camera-equipped mobile phone 1 is transmitted to the authentication server 3 via the provider 2. The authentication server 3 executes authentication based on the authentication data. When the authentication is successful, the authentication server 3 transmits the address information of the print server 5 to the mobile phone 1 with camera via the provider 2.
[0033]
The user's camera-equipped mobile phone 1 authenticated by the authentication server 3 transmits image data to the print server 5. The image data is directly transmitted to one of a plurality of minilab print servers 5 without going through the authentication server 3. The lab where the same user ordered prints last time, the lab near the location selected by the user as the receiving location, the lab near the user's home address, etc. are selected. The selection of these laboratories is performed by the authentication server 3, and the image data is automatically detoured to the selected laboratory. Alternatively, the operating status of the printer may be detected and transmitted to an empty laboratory. Of course, image data of the same user sent within a certain period is sent to the same laboratory and printed.
[0034]
As described above, the image data transmitted from the camera-equipped mobile phone 1 is distributed and received by a plurality of servers, so that even if the image data transmitted from the camera-equipped mobile phone 1 has a large capacity, Traffic is not concentrated only on the server. Therefore, it is possible to reduce that the server goes down due to traffic. In addition, since the user authentication work is collectively executed by the authentication server 3, there is no need to authenticate each print server 5, so there is no security concern. Further, it is not necessary to construct a complicated authentication system in each print server 5.
[0035]
Next, the control of the system of this embodiment will be specifically described.
First, the control executed by the camera-equipped mobile phone 1 will be described. FIG. 6 is a flowchart showing the control executed by the CPU 13. This flow starts when the shutter button 16 is operated by the user in the camera-equipped mobile phone 1 in the camera mode.
[0036]
First, in step S10, an imaging process by the imaging device 11 is performed. In step S11, a display image to be displayed on the monitor 17 is generated from the output data of the image sensor 11 obtained by the imaging process. Since the display image may be an image having a resolution that is satisfactory for display on the monitor 17, the display image is generated by thinning out pixels from the output data of the image sensor 11. In step S12, a display image is displayed on the monitor 17. In step S13, the authentication server 3 is connected via the Internet, and authentication data including user information necessary for the authentication server 3 to perform authentication work is transmitted to the authentication server 3. In step S14, it is detected whether an authentication confirmation signal is received from the authentication server 3. If it is detected that an authentication confirmation signal has been received, the process proceeds to step S15. If no authentication confirmation signal is received, that is, if authentication is rejected, the process proceeds to step S22. The authentication server 3 also transmits address information for connecting to the print server 5 that transmits the image data together with the authentication signal.
[0037]
In step S22, a screen for registering a new user for receiving the service received from the authentication server 3 is displayed. In step S23, it is detected whether the user registration work has been executed according to the user registration screen. When the user registration work is performed, the process returns to step S13 and re-authentication is performed. Further, when the user registration work is not performed, this flow is finished.
[0038]
On the other hand, in step S15, the RAW image data almost unchanged from the output data from the image sensor 11 is transmitted to the print server 5 according to the address information received from the authentication server 3. At this time, the model information of the camera-equipped mobile phone, the shooting environment information, and information such as what recording format is used for storage are added to the RAW image data and transmitted. In addition, when it is set to print the image being transmitted, the print order data is also added to the RAW image data and transmitted.
[0039]
In step S16, it is detected whether transmission of the RAW image data is completed. If the transmission has been completed, the process proceeds to step S17. If the transmission has not been completed, the process returns to step S15 to continue the transmission. In step S <b> 17, end tag information indicating completion of transmission of the captured RAW image data is transmitted to the print server 5. In step S18, the reproduction image data displayed on the monitor 17 is changed to moving image data being captured. Accordingly, it is possible to notify the user that the next shooting is possible and to notify the user that the transmission of the image data is completed. A display indicating that the transmission of the image data has been completed may be performed using characters or the like. In step S19, the image data for reproduction is received from the image storage server 4. The image data for reproduction is image data to be displayed on the monitor 17 when viewing the image data with the camera-equipped mobile phone 1, and is image data based on the data subjected to image processing by the print server 5. It is closer to the image quality (color, contrast) of the image data to be stored and printed than the display image data generated in step S11 immediately after imaging. In step S20, it is detected whether or not the reproduction image data has been received. If the reception is completed, the process proceeds to step S21. If the reception is not completed, the reception of the reproduction image data is continued in step S19. In step S21, the display image data created in step S11 is erased, and the reproduction image data received from the image storage server 4 is stored in the memory card.
[0040]
As described above, the camera-equipped mobile phone 1 according to the present embodiment receives the image data for reproduction subjected to the optimized image processing from the server after the image processing, and automatically replaces the old image data for reproduction and saves it. It is possible to obtain reproduction-use image data that has undergone converted image processing.
[0041]
Further, it is not always necessary to transmit the image data using the communication function of the camera-equipped mobile phone 1. For example, the image data stored in the memory card of the camera-equipped mobile phone 1 can be taken out with a personal computer, and the image data can be transmitted using the personal computer. Lens characteristic information is added to the image data stored in the memory card.
[0042]
Next, the control executed by the authentication server 3 will be specifically described.
First, control executed between the authentication server 3 and the camera-equipped mobile phone 1 will be described. FIG. 7 is a flowchart showing the control executed by the CPU 31.
[0043]
First, in step S31, it is detected whether or not authentication data including user information is received from the camera-equipped mobile phone 1. If the authentication data is received, the process proceeds to step S32. If the authentication data is not received, the process continuously waits for the reception of the authentication data. In step S32, it is searched whether the received authentication data is registered in the customer information in the customer database storage unit 32. In step S33, it is detected whether it is registered in the customer information from the search result. If registered, the process proceeds to step S34, and if not registered, the process proceeds to step S36.
[0044]
In step S34, an optimum laboratory is selected from the customer information of the authenticated user and the laboratory information in the laboratory database storage unit 33. In step S35, the address information of the print server 5 for enabling transmission of image data is transmitted to the print server 5 of the selected laboratory. In step S36, a registration page for performing new customer registration is transmitted to the camera-equipped mobile phone 1. In step S37, it is detected whether registration information according to the registration page has been received from the camera-equipped mobile phone 1 or not. If received, the process proceeds to step S38, and if not received, reception detection of registration information is continued. In step S38, customer information is registered based on the received registration information in the customer database storage unit 32 of the authentication server 3. When registration is completed, the process proceeds to step S34.
[0045]
By controlling in this way, depending on the user of the camera-equipped mobile phone 1, optimization processing of image data and a laboratory for printing image data are selected from a plurality of laboratories, so the processing is concentrated in one laboratory. To prevent the print server from going down.
[0046]
Next, the control of the authentication server 3 executed with the image storage server 4 will be described. FIG. 8 is a flowchart showing the control executed by the CPU 31 of the authentication server 3. This flow starts when a connection with the image storage server 4 is detected.
[0047]
First, in step S51, user information is received from the image storage server 4. In step S52, the customer registration data is accessed, the received user information is searched, and address information for connecting to the user's terminal is acquired. In step S53, the address information of the user is transmitted to the image storage server 4.
[0048]
By controlling in this way, the image storage server 4 can be connected to the user terminal without storing the address of the user's terminal, so that it is possible to secure the memory capacity for storing the user information and the user. There is no worry of information leaking.
[0049]
Next, control of the authentication server 3 executed with the print server 5 will be described.
FIG. 9 is a flowchart showing the control executed by the CPU 31 of the authentication server 3. This flow starts when a connection with the print server 5 is detected.
[0050]
First, in step S61, the latest version information of the image optimization program is transmitted to the print server 5. In step S62, it is detected whether or not there is an instruction to download the latest image optimization program from the print server 5. The download instruction is issued when the optimization program held in the print server 5 is not the latest version. If there is a download instruction, the process proceeds to step S63. If there is no download instruction, this flow ends. In step S63, the download of the latest image optimization program by the print server 5 is permitted.
[0051]
By controlling in this way, the latest image optimization program can always be provided to the print server 5.
Next, control executed by the image storage server 4 will be described. FIG. 10 is a flowchart showing the control executed by the CPU 41 of the image storage server 4. This flow starts when a connection with the print server 5 is detected.
[0052]
First, in step S71, it is detected whether image data is received from the print server 5. If received, the process proceeds to step S72. If not received, the detection is continued. In step S72, the received image data is stored in a hard disk device connected to the image storage server. In step S73, the authentication server 3 is connected. In step S74, the user's address is acquired from the user information attached to the image data. In step S75, reproduction image data is transmitted to the user based on the acquired user address.
[0053]
As described above, in this system, the image data is directly transmitted between the image storage server 4 and the print server 5 without going through the authentication server 3, so that the communication traffic of one server such as the authentication server 3. Can be reduced and server down can be prevented.
[0054]
Next, control executed by the print server 5 will be described.
The print server 5 passes the image data to the printer 6 and controls the printer. Image processing is added to the received image data. When the received image data is RAW data, the image data is subjected to processing such as interpolation and compression.
[0055]
Information such as distortion, chromatic aberration, and peripheral light amount possessed by the lens attached to the camera-equipped mobile phone 1 is received in advance or together with image data. Using this lens information, the received image data is subjected to image processing such as interpolation and compression. It is automatically executed by a program stored in the print server 5. Lens information may be stored in advance in a program.
[0056]
Further, the lens characteristics and the like may be derived by having a user photograph a specific subject and transmitting image data. The lens characteristics are stored for each user, and when image data is transmitted from the corresponding user, image processing is performed according to the lens characteristics and processed into optimum image data. Individual lens characteristics may be collected before the camera-equipped mobile phone 1 is shipped. Further, an instruction to correct an image from a user may be learned. As a result, image deficiencies due to lens characteristics can be eliminated, and user's personal favorite image data can be generated.
[0057]
Hereinafter, control executed by the print server 5 will be described with reference to a flowchart. FIG. 11 is a flowchart showing the control executed by the CPU 51 of the print server 5.
[0058]
First, in step S100, it is detected whether or not image data has been received via a communication line. If the reception of image data is detected, the process proceeds to step S101. If the reception of image data is not detected, the detection is continued. In step S101, the received image data is stored in the hard disk device 55. Subsequently, in step S102, it is detected whether the reception of the image data is completed. Whether or not the processing has ended can be detected from the end tag information transmitted from the user together with the image data. If completed, the process proceeds to step S103. If not completed, the process returns to step S101 and continues to receive and store image data.
[0059]
In step S103, the authentication server 3 is connected via a communication line. In step S104, the latest version information of the image optimization program is received from the authentication server 3. Next, in step S105, it is compared with the version of the image optimization program registered in the print server 5, and it is determined whether or not the registered image processing program is the latest version. If it is the latest version, the process proceeds to step S108, and if it is not the latest version, the process proceeds to step S106. In step S106, data for updating to the latest version is downloaded from the authentication server 3. In step S107, the old data and the latest data are exchanged. By upgrading to the latest version of the image optimization program, it is possible to cope with image data taken with a new model camera, and it is also possible to correspond to the latest image processing technology and compression technology. You can also fix bugs in the previous version.
[0060]
In step S108, the image optimization program is activated. In step S109, image optimization processing is performed on the received image data.
Next, the image optimization process control executed in step S109 will be described. FIG. 12 is a flowchart showing the control executed by the CPU 51.
[0061]
First, in step S200, the data format of the received image data is detected, and it is determined whether or not it is RAW data. If it is RAW data, the process proceeds to step S202, and if it is not RAW data, the process proceeds to step S201. In step S201, the received image data is reproduced. In the reproduction process, if the image data is compressed by a method such as JPEG, the image data is expanded and an image that can be processed is generated.
[0062]
In step S202, interpolation processing is performed on the received RAW format image data to generate an optimal image. In step S203, aberration information of the photographed camera is acquired. In step S204, image processing for eliminating aberration and the like is performed based on the acquired information. In step S205, it is detected from the received data whether or not a print order has been made for the processed image. If an order has been placed, the process proceeds to step S206, and if no order has been placed, the process proceeds to step S207.
[0063]
In step S206, information such as the number of prints and print size according to the print order and image information are transmitted to the printer. In step S207, the image data subjected to image processing is subjected to processing such as image size conversion and image compression in accordance with the received data storage method information, and is stored in the hard disk device.
[0064]
In step S208, it is detected whether image data transmitted from the user and not subjected to image processing exists in the hard disk device. If it exists, the process returns to step S200, and the processing from step S200 to step S207 is performed on the new image data. If it does not exist, the process proceeds to step S209. In step S209, the image storage server 4 is connected. Subsequently, in step S210, image processing and image data stored in the hard disk device 55 are transmitted to the image storage server 4.
[0065]
The camera-equipped mobile phone 1 has a function of performing image editing processing such as trimming, composition, image editing, and frame attachment on image data. At the time of editing work on the camera-equipped mobile phone 1, it is virtually performed using the reproduction image data. When the image editing is completed, the camera-equipped mobile phone 1 transmits the content information of the applied image editing to the image storage server 4. The image storage server 4 performs image editing on the stored image data based on the image editing content information.
[0066]
The edit control executed by the system of this embodiment will be specifically described below.
First, editing control executed by the camera-equipped mobile phone 1 will be described. FIG. 13 is a flowchart showing the control executed by the CPU 13. It starts when editing work is started on the camera-equipped mobile phone 1.
[0067]
In step S301, the contents of the image editing work are stored. In step S302, it is detected whether or not the editing operation has been completed. If it has been completed, the process proceeds to step S303. If it has not been completed, storage of the editing work is continued. In step S <b> 303, the stored content data of editing work and image data information to be edited are transmitted to the image storage server 4. In step S304, the image data for reproduction is received from the image storage server 4. In step S305, it is detected whether or not the reception of the reproduction image data has been completed. If completed, the process proceeds to step S306. If not completed, reception of the reproduction image data is continued. In step S306, the stored reproduction image data is erased and the received reproduction image data is stored.
[0068]
Next, control executed by the image storage server 4 will be described. FIG. 14 is a flowchart showing the control executed by the CPU 41.
In step S401, it is detected whether image data information to be edited and editing work content data have been received from the camera-equipped mobile phone 1. If received, the process proceeds to step S402, and if not received, reception detection is continued. In step S402, the image storage memory 42 is searched for image data to be edited. In step S403, image editing is performed on the image data to be edited according to the editing work content data. In step S404, the original image data in the image storage memory 42 is deleted and the edited image data is stored. In step S405, reproduction image data to be reproduced by the camera-equipped mobile phone 1 is generated from the edited image data. In step S406, the generated image data for reproduction is transmitted to the camera-equipped mobile phone 1.
[0069]
By controlling in this way, the image editing performed by the camera-equipped mobile phone 1 is also reflected in the image data stored in the image storage server 4. Also, the image data for reproduction of the camera-equipped mobile phone 1 automatically becomes an image corresponding to the edited image.
[0070]
Some digital cameras have a function of replaying and displaying image data taken immediately after shooting for a predetermined time and confirming the shot image. In addition, there is a camera provided with a function of easily deleting an image captured by a simple operation within a predetermined time during reproduction and display. In the camera-equipped mobile phone 1 of the present embodiment, image data is transmitted after shooting. When the camera-equipped mobile phone 1 has the function of easily deleting the image data, it is necessary to delete the image data that has been transmitted once, which increases communication cost and control load. Therefore, the camera-equipped mobile phone 1 controls to wait for communication for a predetermined time after shooting and transmit only image data that has not been deleted within the predetermined time.
[0071]
FIG. 15 is a flowchart showing the control executed by the camera-equipped mobile phone 1. This flow starts when the shutter button 16 is operated by the user in the camera-equipped mobile phone 1 in the camera mode. Further, after the connection to the authentication server 3, the same control as step S14 in FIG.
[0072]
First, in step S501, imaging processing by the imaging device 11 is performed. In step S502, a display image to be displayed on the monitor 17 is generated from the output data of the image sensor 11 obtained by the imaging process. Since the display image may be an image having a resolution that is satisfactory for display on the monitor 17, the display image is generated by thinning out pixels from the output data of the image sensor 11. In step S503, a display image is displayed on the monitor 17, and a display for inquiring whether to delete the image is performed. FIG. 16 shows a display example. In FIG. 16, a delete button 252 is displayed at the lower right of the image 251 obtained by shooting. By operating the delete button 252, the image data of the image 251 can be easily deleted. The monitor 17 is provided with a touch panel and can be operated by directly touching the delete button 252. In step S504, it is detected whether a predetermined time has elapsed since the display image was displayed. If the predetermined time has elapsed, the process proceeds to step S506, and if the predetermined time has not elapsed, the process proceeds to step S505. In step S505, it is detected whether or not the delete button 252 has been operated. If the deletion operation has been performed, the process proceeds to step S507. If the deletion operation has not been performed, the process returns to step S504. In step S507, the display image data is deleted.
[0073]
In step S506, the authentication server 3 is connected via the Internet, and authentication data including user information necessary for the authentication server 3 to perform authentication work is transmitted to the authentication server 3. In step S508, the above-described image transmission control such as transmission of RAW image data to the print server 5 is executed.
[0074]
Thereby, the communication cost and control load of the camera-equipped mobile phone 1 that transmits large-capacity image data such as RAW image data can be reduced.
(Second Embodiment)
Next, a camera system according to a second embodiment of the present invention will be described. The camera system of the second embodiment is a system that cooperates with an in-vehicle computer mounted in a car, and in particular, a camera system in a rental car will be described as an example.
[0075]
FIG. 17 is a block diagram illustrating a camera system according to the second embodiment. In FIG. 17, the camera system mainly includes a camera-equipped mobile phone 101, a cradle 102, an in-vehicle computer 201, a monitor 107, a microphone 108, a speaker 109, and a controller 110. The in-vehicle computer 201 includes a communication circuit 103, a CPU 104, a hard disk drive (HDD) 105, a display circuit 106, and a GPS sensor 111. The print server 301 is a server computer that receives a print order from the in-vehicle computer 201.
[0076]
Similar to the camera-equipped mobile phone 1 of the first embodiment, the camera-equipped mobile phone 101 has a call function as a mobile phone, a mail function as an Internet terminal, a WEB browsing function, and the like. It also has a camera part and functions as a digital camera. A memory card slot is provided, and image data picked up by the camera unit is stored in a mounted memory card. The camera-equipped mobile phone 101 also functions as a rental car key. That is, it is possible to remotely instruct door lock and door lock release. In the case of an engine car, the engine can be instructed to start and stop. Note that in order to provide the camera-equipped mobile phone 101 with a key function, it is necessary to register key information specific to a rental car to be rented to the mobile phone 101.
[0077]
The cradle 102 is connected to the in-vehicle computer 201 and is used for data transmission / reception between the mounted mobile phone 101 with a camera and the in-vehicle computer 201. The cradle 102 has a function of charging the rechargeable battery of the camera-equipped mobile phone 101. Further, the cradle 102 is provided with an operation button for starting transfer of image data in the mounted mobile phone 101 with a camera to the in-vehicle computer 201. The user selects in advance by the camera-equipped mobile phone 101 whether to start image data simply by placing the camera-equipped mobile phone 101 on the cradle 201 or to start image data when the operation button is operated. Can be kept.
[0078]
The in-vehicle computer 201 includes a communication circuit 103, a CPU 104, an HDD 105, a display circuit 106, and a GPS sensor 111, and can perform the same function as a personal computer. The communication circuit 103 is a circuit for wirelessly connecting to an external server computer and transmitting / receiving data. The CPU 104 is a circuit that performs processing for realizing a function executed by the in-vehicle computer 201. The HDD 105 is a device for storing various data as well as programs for realizing various functions. The display circuit 106 is a circuit that generates a screen to be displayed on the monitor 107. The GPS sensor 111 is a sensor used for detecting position information of a rental car and enables a car navigation function.
[0079]
The operation of the camera system of the second embodiment will be described.
The in-vehicle computer 201 is always in a standby state, and the main power supply can be turned on by receiving some signal. This provides for accidents such as theft. Even when the camera-equipped mobile phone 101 is connected to the cradle 102, the power is turned on, and a program of a function performed in cooperation with the camera-equipped mobile phone 101 such as sucking up an image can be executed.
[0080]
Specifically, it is detected whether large-size captured image data exists in the camera-equipped mobile phone 101. If large-size image data exists, image data is downloaded. Further, the rechargeable battery of the camera-equipped mobile phone 101 is charged. The transfer of the image data may be executed using wireless communication such as Bluetooth without using the cradle 102. In addition, the cradle 102 and the in-vehicle computer 201 may not be connected with a wired cable, but wireless communication such as Bluetooth may be used.
[0081]
The in-vehicle computer 201 interpolates and processes the RAW data received from the camera-equipped mobile phone 101 to generate image data. The in-vehicle computer 201 has a JPEG compression / reproduction function for image data received from a camera. This is used for compressing and reproducing image data for reproduction and reproducing image data downloaded by WEB.
[0082]
The in-vehicle computer 201 makes it possible to browse the image data sucked from the camera-equipped mobile phone 101 on the monitor 107. A print order can be made while browsing on the monitor 107. When a print order is placed, it is detected whether communication is possible. If the communication is not possible, the image data and the order information are temporarily stored in the HDD 105 until the transmission is completed.
[0083]
Hereinafter, the image data siphoning control of the camera-equipped mobile phone 101 executed by the in-vehicle computer 201 will be described. FIG. 18 is a flowchart showing image data siphoning control executed by the in-vehicle computer 201.
[0084]
First, in step S900, it is detected whether or not a device is connected. If detected, the process proceeds to step S901. If not detected, the detection is continued. In step S901, an instruction is sent to the connected device to transmit an identification signal. The in-vehicle computer 201 can acquire an identification signal for identifying a device from the device without using the power source of the device itself by passing a weak current to the connected device according to the standard. In step S902, it is detected whether an identification signal has been received from the connected device. If it is detected that the identification signal has been received, the process proceeds to step S903. If it is not detected that the identification signal has been received, reception detection is continued. In step S903, it is determined from the identification signal whether the connected device is the camera-equipped mobile phone 101. If it is the camera-equipped mobile phone 101, the process proceeds to step S905. If it is not the camera-equipped cellular phone 101, the process proceeds to step S904. In step S904, control programmed according to the connected device is executed. In step S905, a program suitable for the connected camera-equipped mobile phone 101 is read and executed. In step S906, an instruction is given to supply power to a circuit necessary for controlling the camera-equipped mobile phone 101.
[0085]
In step S907, it is detected whether image data of a predetermined size or larger exists in the camera-equipped mobile phone 101. Here, the image data of a predetermined size or larger is RAW image data or the like that is not reproduction image data generated for viewing on the monitor of the camera-equipped mobile phone 101. If image data of a predetermined size or larger exists, the process proceeds to step S908. If image data of a predetermined size or larger does not exist, the process proceeds to step S916. In step S908, image data of a predetermined size or larger existing in the camera-equipped mobile phone 101 is sucked up. Suck up the image data from the oldest shooting date. Print order data, storage environment data, etc. are downloaded together with image data. The print ordering data is data for ordering prints from a laboratory, and includes data such as the number of prints, print size, and receiving location. The storage environment data is data including an image size, a compression rate, a storage location, and the like when storing the image data.
[0086]
In step S909, it is detected whether the downloading of image data has been completed. If the siphoning has been completed, the process proceeds to step S910. If it has not been completed, the process returns to step S908 to continue the image data siphoning. In step S910, it is determined whether the image data for which the siphoning has been completed is RAW image data. If the image data is RAW image data, the process proceeds to step S911. If the image data is not RAW image data, the process proceeds to step S912. In step S911, processing such as pixel interpolation is performed so that the sucked-in RAW image data can be reproduced. In step S912, image processing for optimizing the sucked image data is performed. A camera-equipped mobile phone sacrifices lens performance and the like because the camera mechanism needs to be downsized. For this reason, the photographed image has an influence such as chromatic aberration. The image processing to be optimized is image processing that reduces or removes the influence of chromatic aberration or the like existing for each model or each camera.
[0087]
In step S913, the image data is compressed according to the storage environment data. In step S914, the image data is stored in the HDD 105. In step S915, an instruction is given to delete image data in the camera-equipped mobile phone 101 that has been sucked up. Alternatively, if the storage environment data is set to save image data in the camera-equipped mobile phone 101, the image data is transmitted to the camera-equipped mobile phone 101, and is overwritten and saved by replacing the sucked-up image data. When the process of step S915 ends, the process returns to step S907.
[0088]
In step S916, the camera-equipped mobile phone 101 is turned off. In step S917, the print order data is analyzed to determine whether there is image data to be ordered. Further, the storage environment data is analyzed to determine whether there is image data for storing the image data outside. If there is image data corresponding to any of these, the process proceeds to step S918, and if not, the process proceeds to step S919.
[0089]
In step S918, image data to be ordered for printing or image data whose storage destination is an external computer is put into a standby state for transmission to the external computer. In step S919, it is detected whether the rechargeable battery of the camera-equipped mobile phone 101 needs to be charged. If charging is necessary, the process proceeds to step S920; otherwise, the process proceeds to step S921. In step S920, charging of the rechargeable battery is started. In step S921, the camera-equipped mobile phone 101 and itself are placed in a standby state, and the camera control process is terminated.
[0090]
Hereinafter, the image data siphoning control of the camera-equipped mobile phone 101 executed by the in-vehicle computer 201 will be described. FIG. 19 is a flowchart showing image data processing control executed by the in-vehicle computer 201. This flow starts by detecting that the camera-equipped mobile phone 101 is placed on the cradle 102 connected to the in-vehicle computer 201.
[0091]
First, in step S931, it is detected whether or not an operation button for starting the siphoning of image data provided in the cradle 102 has been operated. If detected, the process proceeds to step S932, and if not detected, the process proceeds to step S942. In step S932, an instruction is given to supply power to a circuit necessary for controlling the camera-equipped mobile phone 101.
[0092]
In step S933, it is detected whether image data of a predetermined size or larger exists in the camera-equipped mobile phone 101. Here, the image data of a predetermined size or larger is RAW image data or the like that is not reproduction image data generated for viewing on the monitor of the camera-equipped mobile phone 101. If image data of a predetermined size or larger exists, the process proceeds to step S934. If image data of a predetermined size or larger does not exist, the process proceeds to step S941. In step S934, image data of a predetermined size or larger existing in the camera-equipped mobile phone 101 is sucked up. Absorbs storage environment data as well as image data. The storage environment data is data including an image size, a compression rate, a storage location, and the like when storing the image data. Suck up the image data from the oldest shooting date.
[0093]
In step S935, it is detected whether the downloading of the image data has been completed. If the sucking has been completed, the process proceeds to step S936. If not completed, the process returns to step S934 to continue the image data sucking. In step S936, it is determined whether the image data for which the siphoning has been completed is RAW image data. If the image data is RAW image data, the process proceeds to step S937. If the image data is not RAW image data, the process proceeds to step S938. In step S937, processing such as pixel interpolation is performed so that the sucked-in RAW image data can be reproduced.
[0094]
In step S939, the image data is subjected to compression processing or the like according to the storage environment data. In step S940, the processed image data is transmitted to the camera-equipped mobile phone 101 in order to replace the image data before the image processing existing in the camera-equipped cellular phone 101 with the image data processed by the in-vehicle computer 201. Then, the processed image data is overwritten and saved on the unprocessed image data. Then, returning to step S933, if there is image data other than the processed image data, the control from step S934 to step S940 is repeated.
[0095]
In step S941, the camera-equipped mobile phone 101 is turned off. In step S942, it is detected whether or not the rechargeable battery of the camera-equipped mobile phone 101 needs to be charged. If charging is necessary, the process proceeds to step S943, and if not, the flow ends. In step S943, the rechargeable battery is charged. Subsequently, in step S944, it is detected whether charging of the rechargeable battery is completed. If the charging is completed, the process proceeds to step S945. If the charging is not completed, the process returns to step S943 and the charging process is continued. In step S945, the charging process of the rechargeable battery is terminated.
[0096]
As described above, image processing that cannot be performed by the camera-equipped mobile phone 101 itself is executed by the in-vehicle computer 201, and control is performed so as to return to the camera-equipped mobile phone 101 after execution. Advanced image processing can be executed. In addition, since the above control is realized simply by placing the camera-equipped mobile phone 101 on the cradle 102 and operating the operation switch, the user is not burdened. Further, since the processed image data is returned to the camera-equipped mobile phone 101, the processed image data can be carried along with the camera-equipped mobile phone 101.
[0097]
When the automobile is stopped or when a passenger is present, driving is not disturbed, so various operations can be performed while watching the monitor 107. Therefore, the in-vehicle computer 201 executes different control depending on whether the automobile is stopped or there is a passenger. When the car is stopped or there are passengers, it is possible to perform operations such as ordering prints of the sucked image data without hindering driving, so the list display of sucked image data can be displayed on the monitor 107. Display and operate the monitor 107 to enable print ordering.
[0098]
FIG. 20 is a flowchart showing the control executed by the in-vehicle computer 201.
First, in step S951, it is detected whether the camera-equipped mobile phone 101 is placed on the cradle 102 or not. If it is detected that it has been placed, the process proceeds to step S952, and if it is not detected, the detection is continued.
[0099]
In step S952, the traveling state of the automobile and the presence or absence of a passenger are detected. In step S953, it is determined whether the vehicle is stopped or whether a predetermined condition such as the presence of a passenger is cleared. If the predetermined condition is cleared, the process proceeds to step S954, and if not cleared, the process proceeds to step S966.
[0100]
In step S954, it is detected whether image data of a predetermined size or more exists in the camera-equipped mobile phone 101. When it exists, it progresses to step S955, and when it does not exist, this flow is complete | finished.
[0101]
In step S955, image data is downloaded. In step S956, it is detected whether any function displayed on the monitor 107 is being executed. Some functions displayed on the monitor 107 include setting of a driving route for car navigation, watching TV, watching movies, browsing the Internet, and the like. If it has been executed, the process proceeds to step S957. If it has not been executed, the process proceeds to step S959. In step S957, a display for inquiring whether to display image data is overlapped with the display of the function being executed and displayed on the monitor 107. FIG. 21 shows an example of a screen displayed on the monitor 107. In the display example of FIG. 21, a character 245 for inquiring whether to display a list of sucked images that overlap with the car navigation display, and an image display button 246 for instructing image display are displayed. By operating the image display button 246, it is possible to switch to a list display of image data sucked from the camera-equipped mobile phone 101.
[0102]
In step S958, it is detected whether or not the image display button 246 has been operated. If operated, the process proceeds to step S959, and if not operated, the process proceeds to step S960. In step S960, it is detected whether a predetermined time has elapsed. If the predetermined time has elapsed, the process proceeds to step S961, and if the predetermined time has not elapsed, the process returns to step S958. In step S961, the display is switched from the display of FIG. 21 to the display in which the characters 245 as the inquiry display and the image display button 246 are removed.
[0103]
In step S959, the display on the monitor 107 is switched to the list display of the sucked image data. FIG. 22 shows a display example. A print order for the print size and the number of prints can be instructed for each image. In FIG. 22, when the image portion 251 of the image displayed as a list is operated, the operated image can be enlarged and displayed as one image on the entire monitor 107 screen. 22 shows that the user has already instructed the image 2 to be printed with the service size as the size and the number of sheets as one. When the print order button 252 is operated, a print order is placed on the print server 301. The list display is displayed in order of images with the oldest shooting date and time.
[0104]
In step S962, it is detected whether or not the print order button 252 has been operated. If it is operated, the process proceeds to step S963, and if it is not operated, this flow is ended. In step S963, image data ordered for printing is extracted. In step S964, the above-described optimization process is executed on the extracted image data. If the image data ordered for printing is raw image data, processing such as pixel interpolation is also performed. In step S965, the optimized image data is transmitted to the print server 301.
[0105]
On the other hand, in step S966, it is detected whether image data exists. When it exists, it progresses to step S967, and when it does not exist, this flow is complete | finished. In step S967, image data siphoning is executed.
[0106]
In the above-described control, for safety reasons, the vehicle can be operated only when conditions such as when the vehicle is stopped or when a passenger is present, but the vehicle does not interfere with driving such as automatic driving. When a function is added, the operation may be performed without clearing such a condition.
[0107]
Even if the conditions are cleared, the user does not know whether he / she wants to display image data or place a print order. Therefore, when displaying other functions such as car navigation, the display on the monitor 107 is displayed. Give priority to the display of car navigation without switching to. Of course, not only the display but also the processing in the in-vehicle computer 201 gives priority to the car navigation. Further, even if the conditions are not cleared, the image siphoning control that does not require user operation and display on the monitor 107 is executed.
[0108]
In the above control, pixel interpolation processing and optimization processing are performed only on the image data to be transmitted to the print server 301 for which the print order has been placed. By processing when using the image data, the image data that is not the target of the print order this time is not subjected to the optimization process. It will not be applied. Further, when image data not ordered for printing this time is used in the future, the optimization processing program may be upgraded and further optimized.
[0109]
In the control executed by the in-vehicle computer 201 described below, pixel interpolation processing and image optimization processing are performed on image data for which no print order has been placed. In addition, image data for which a print order has been placed is transferred to the print server 301 as it is. That is, image data transmitted to the print server 301 is subjected to pixel interpolation processing and image optimization processing by the print server 301, and image data not transmitted to the print server 301 is subjected to pixel interpolation processing and image optimization processing by the in-vehicle computer 201. Applied. Further, the image data subjected to the image optimization processing by the print server 301 and the in-vehicle computer 201 is transmitted to one image storage server and stored in a batch.
[0110]
FIG. 23 is a flowchart showing the control executed by the in-vehicle computer 201. This flow starts by detecting the user's print order instruction.
[0111]
First, in step S971, the image data ordered for printing is transmitted to the print server 301 as RAW image data. The image data transmitted to the print server 301 is subjected to pixel interpolation processing and image optimization processing in the print server 301, printed, and transmitted to and stored in a predetermined image storage server. In step S972, the image data transmitted to the print server 301 is deleted from the HDD 105. In step S973, pixel interpolation processing is performed on image data remaining in the HDD 105, that is, image data that has not been ordered for printing. In step S974, an image optimization process is performed on the image data subjected to the pixel interpolation process. In step S975, connection is made to a predetermined image storage server. The predetermined image storage server is the same server as the server to which the print server 301 transmitted image data. Subsequently, in step S976, the processed image data is transmitted to a predetermined image storage server. In step S977, it is detected whether transmission of image data to a predetermined image storage server is completed. If it has been completed, the process proceeds to step S978. If it is not completed, the process returns to step S976. In step S978, the image data that has been transmitted to the predetermined image storage server is deleted from the HDD 105.
[0112]
In the above example, in order to centrally manage the image data, the processed image data is transmitted to and stored in a predetermined image storage server in which the image data ordered for printing is stored. You may make it store in HDD105, without transmitting.
[0113]
Next, a description will be given of control that prioritizes other functions than downloading and displaying image data in the camera-equipped mobile phone 101. When other functions are being executed, priority is given to the other functions even if the downloading of image data is executed. If another function is executed during the image data downloading, the image sucking control is temporarily interrupted to prioritize the execution of the other function.
[0114]
FIG. 24 is a flowchart showing the control executed by the in-vehicle computer 201. This flow starts by detecting that the camera-equipped mobile phone 101 is placed on the cradle 102.
[0115]
First, in step S981, it is detected whether image data exists in the camera-equipped mobile phone 101. If the image data exists, the process proceeds to step S982, and if the image data does not exist, this flow ends. In step S982, it is detected whether there is a function already executed such as navigation. If there is, the process proceeds to step S983, and if not, the process proceeds to step S986. In step S983, it is detected whether the siphoning of the image data affects the function. If there is an influence, the process proceeds to step S984, and if there is no influence, the process proceeds to step S986. In step S984, image data siphoning processing is awaited. In step S985, it is detected whether the function being executed is no longer affected. If the influence is no longer exerted, the process proceeds to step S986. If the influence is exerted, the process returns to step S984 to wait for the image siphoning process.
[0116]
In step S986, image data siphoning processing is executed. In step S987, it is detected whether the image data siphoning process has been completed. If the siphoning process has been completed, this flow is terminated. If the siphoning process has been completed, the process returns to step S982.
[0117]
With the above control, the siphoning process of image data does not adversely affect the execution of other functions.
Next, another control executed by the in-vehicle computer 201 will be described.
[0118]
When the in-vehicle computer 201 is in the car navigation mode, the reception of necessary map information is automatically started by placing the camera-equipped mobile phone 101 on the cradle 102. Naturally, map information corresponding to the current position of the vehicle is received.
[0119]
Further, by simply placing the camera-equipped mobile phone 101 on the cradle 102, the speaker 109 and the microphone 108 in the vehicle can be connected to make a hands-free call. The monitor 107 can be used to function as a videophone.
[0120]
In addition, if the amount of data is large, communication costs are increased and other functions such as a navigation function may be affected. When the communication function of the camera-equipped mobile phone 101 is used, the priority order of image transmission is the lowest. Of course, if another communication is necessary during the communication of the image data, the communication of the image data is temporarily interrupted.
[0121]
Also, in the case of communication using a wireless LAN in a hot spot without using the communication function of the camera-equipped mobile phone 101, the transmission priority of image data is set lower than that of map data transmission / reception. .
[0122]
The control executed by the in-vehicle computer 201 will be described below. FIG. 25 is a flowchart showing the control executed by the in-vehicle computer 201. This flow starts when the camera-equipped mobile phone 101 is placed on the cradle 102 and connected to the in-vehicle computer 201.
[0123]
First, in step S1001, it is detected whether or not the mode being executed by the in-vehicle computer 201 is the car navigation mode. If it is in the car navigation mode, the process proceeds to step S1002, and if it is not in the car navigation mode, the process proceeds to step S1013. In step S1002, it is detected whether the wireless LAN communication is possible within the hot spot area. If wireless LAN communication is possible, the process proceeds to step S1003. If wireless LAN communication is not possible, the process proceeds to step S1010. In step S1003, data for acquiring map data, guide data and the like necessary for car navigation is transmitted and received. In step S1004, it is detected whether image data to be transmitted to the external computer exists in the camera-equipped mobile phone 101. If it exists, the process proceeds to step S1005, and if it does not exist, this flow ends. In step S1005, the image data in the camera-equipped mobile phone 101 is sucked up. In step S1006, the image data acquired via the wireless LAN is transmitted to the external computer. In step S1007, it is detected whether there is data to be transmitted / received in order to acquire map data, guide data, and the like necessary for car navigation. If there is data, the process proceeds to step S1008, and if there is no data, the process proceeds to step S1009. In step S1008, transmission of image data is temporarily stopped, and data for car navigation is transmitted and received. In step S1009, it is detected whether transmission of image data is completed. If it has been completed, this flow ends. If it has not been completed, the process returns to step S1006 to continue image data transmission.
[0124]
On the other hand, in step S1010, it is detected whether communication using the communication function of the camera-equipped mobile phone 101 is possible. At present, the area that can be communicated with a mobile phone is far wider than the area that can communicate with a wireless LAN. If communication is possible, the process proceeds to step S1011. If communication is not possible, the process returns to step S1002, and detection is continued until communication is possible using a wireless LAN or a mobile phone. In step S1011, map data, guide data, and the like necessary for car navigation are received. In step S1012, it is detected whether image data to be transmitted to the external computer exists in the camera-equipped mobile phone 101. If it exists, the process proceeds to step S1013. If it does not exist, this flow ends. In step S1013, the image data in the camera-equipped mobile phone 101 is sucked up.
[0125]
In step S1014, the image processing described in steps S910 to S913 in FIG. The processing of reducing the amount of data by compressing the image data is also performed, thereby reducing the communication burden of the mobile phone having a lower communication speed than the wireless LAN. In step S1015, the image data subjected to image processing is transmitted to the external computer via the communication network of the camera-equipped mobile phone 101. In step S1016, it is detected whether there is data to be transmitted / received in order to acquire map data, guide data, and the like necessary for car navigation. If there is data, the process proceeds to step S1017, and if there is no data, the process proceeds to step S1018. In step S1017, transmission of image data is temporarily stopped, and data for car navigation is transmitted and received. In step S1018, it is detected whether transmission of image data is completed. If it has been completed, this flow ends. If it has not been completed, the process returns to step S1015 to continue image data transmission.
[0126]
On the other hand, in step S1019, it is detected whether or not the mode being executed by the in-vehicle computer 201 is the call mode. If the call mode is set, the process proceeds to step S1020. If the call mode is not set, the flow ends. In step S1020, call control to be described later is executed.
[0127]
By controlling as described above, data such as car navigation is transmitted / received with priority over image data transmission, so that there is no problem with car navigation. In addition, communication time and communication costs can be reduced by performing wireless LAN communication with priority over the communication function of the camera-equipped mobile phone 101.
[0128]
Next, the call control executed in step S1020 in FIG. 25 will be described.
FIG. 26 is a flowchart showing call control executed by the in-vehicle computer 201.
[0129]
In step S 1101, the received voice of the other party is made reproducible on the speaker 109. In step S1102, the voice picked up by the microphone 108 can be transmitted to the call partner. In step S1103, it is detected whether the other party's telephone is transmitting image data by videophone. If it is a videophone, the process proceeds to step S1104. If it is not a videophone, the process proceeds to step S1106. In step S1104, the monitor 107 is turned on so that the image data of the other party can be displayed. In step S1105, it is detected whether or not a telephone call is started. If the call is started, the process proceeds to step S1106. If the call is not started, the detection is continued. In step S1106, a callable state of the speaker 109 or the like is maintained. In step S1107, it is detected whether or not the call has ended. If the call has ended, the process proceeds to step S1108. If the call has not ended, the process returns to step S1106. In step S1108, the callable state of the speaker 109 or the like is canceled. In step S1109, it is detected whether image data to be transmitted to the external computer exists in the camera-equipped mobile phone 101. When it exists, it progresses to step S1110, and when it does not exist, this flow is complete | finished. In step S1110, image data to be transmitted to the external computer is downloaded. In step S1111, image processing is performed on the sucked image data. In step S1112, the image data subjected to image processing is transmitted to an external computer.
[0130]
By controlling as described above, the vehicle-mounted speaker 109, microphone 108, and monitor 107 can be automatically used for calling simply by placing the camera-equipped mobile phone 101 on the cradle 102. can do.
[0131]
Furthermore, another control executed by the in-vehicle computer 201 will be described.
Display hotspots and their communicable areas using navigation location information. Conventionally, there is a display of whether inside or outside the hot spot area. However, when outside the area, I didn't know which direction to move into the area. On the other hand, this system can know the hot spot area even when it is not in the hot spot area, so there is no need to search for the hot spot in the dark clouds. You can rest and communicate. The hot spot area is automatically displayed only when data such as image data captured by the camera-equipped mobile phone 101 is set to communicate with the outside.
[0132]
Further, setting means for setting whether or not to display the hot spot area may be provided. Further, when the communication data is not in a standby state, the hot spot area is not displayed because it is annoying if the hot spot area is displayed over the navigation map.
[0133]
FIG. 27 is a flowchart showing the control executed by the in-vehicle computer 201.
In step S2001, it is detected whether or not the navigation mode is set. If it is in the navigation mode, the process proceeds to step S2002. If it is not in the navigation mode, the detection is continued in step S2001. In step S2002, it is detected whether there is data waiting for communication. When it exists, it progresses to step S2003, and when it does not exist, it progresses to step S2005. In step S2003, registered hot spot information is searched. In step S2004, the map information for navigation and the searched hot spot information are combined. In step S2005, a navigation screen as shown in FIG.
[0134]
Naturally, it is displayed in different colors so that it can be distinguished whether it is a hot spot that can be used by an in-vehicle computer while riding a car or a portable device that can be used by taking a portable device indoors. In addition, it is possible to select either an outdoor spot or an indoor spot and display only one of them. It also displays the call area of the mobile phone.
[0135]
The in-vehicle computer 201 includes a hot spot mode in which a travel route passing through a hot spot is preferentially calculated as a navigation function. The hot spot mode is selected when it is desired to transmit data such as image data while traveling. When a plurality of routes are calculated, hot spot information, travel distance to arrival, and estimated travel time are displayed for each route. The user can then select a route.
[0136]
In addition, it is possible to calculate a route by determining a hot spot that the user wants to stop in advance.
FIG. 29 is a flowchart showing travel route calculation control executed by the in-vehicle computer 201.
[0137]
In step S3001, it is detected whether or not the hot spot mode is set. If it is set, the process proceeds to step S3002, and if it is not set, the process proceeds to step S3008. In step S3002, a hot spot database is searched. In step S3003, it is detected whether or not a hot spot exists in a plurality of travel routes toward the set destination. If a hot spot exists, the process proceeds to step S3004, and if not, the process proceeds to step S3007. In step S3004, map information is acquired. In step S3005, a travel route is calculated from the map information and hot spot information. In step S3006, the calculated travel route information is displayed. FIG. 30 is a display example showing travel route information in the hot spot mode. In FIG. 30, the input destinations are displayed in the order of travel routes with the largest amount of data that can be transmitted. For example, in travel route 1, the amount of data that can be transmitted before reaching the destination is 300 MB, the travel distance is 40 km, the required time is 1 hour 30 minutes, and the toll road charge is 0 yen. Yes. The transmittable data amount is an expected data amount because it greatly depends on the traveling speed when passing through the hot spot. By operating the selection button 301, the travel route is determined. When changing the destination, the destination change button 302 is operated. When it is desired to change to a travel distance priority mode other than the hot spot mode, a required time priority mode, or the like, the navigation mode change button 303 is operated. Note that the monitor 107 is a touch panel and can operate buttons directly displayed.
[0138]
On the other hand, in step S3007, a display indicating that there is no travel route passing through the hot spot before reaching the destination is performed. In step S3007, map information is acquired. In step S3008, the travel route that can arrive in the shortest time as in the normal navigation mode is displayed.
[0139]
Thus, by controlling, it is possible to select a travel route that prioritizes passing through the hot spot area, which is useful when there is data to be transmitted during travel.
[0140]
Also, in the control described below, the hot spot area is automatically set when the user is in a transmission standby state where there is data to be transmitted to an external server computer or the like without selecting the hot spot mode by the user. Guide the travel route that passes a lot.
[0141]
Control executed by the in-vehicle computer 201 will be described. FIG. 31 is a flowchart showing the control executed by the in-vehicle computer 201.
In step S3021, it is detected whether there is data such as image data waiting for transmission. When it exists, it progresses to step S3022, and when it does not exist, it progresses to step S3028. In step S3022, the hot spot database is searched. In step S3023, it is detected whether or not a hot spot exists in a plurality of travel routes toward the set destination. If a hot spot exists, the process proceeds to step S3024, and if not, the process proceeds to step S3027. In step S3024, map information is acquired. In step S3025, a travel route is calculated from the map information and the hot spot information. In step S3026, a navigation screen equivalent to the display example shown in FIG. 28 is displayed.
[0142]
On the other hand, in step S3027, a display indicating that there is no travel route passing through the hot spot before reaching the destination is performed. In step S3027, map information is acquired. In step S3028, a travel route that can arrive in the shortest time as in the normal navigation mode is displayed. In step S3030, it is detected whether the user's automobile has arrived at the destination. If it has arrived, this flow ends. If not, the process returns to step S3021. That is, this control is repeatedly executed until it reaches the destination. Therefore, when the vehicle deviates from a different travel route, it checks again whether a hot spot exists and searches for a new travel route. In addition, for example, when image data captured during traveling is newly in a transmission standby state, it is possible to automatically switch from a normal traveling route to a traveling route that prioritizes hot spots.
[0143]
Next, data communication control executed by the in-vehicle computer 201 will be described. The communication area of mobile phones can communicate over a wide range, but there are problems in terms of communication speed and communication charges. The image data photographed by the camera is controlled so that the communication of the image data waits until entering the hot spot. Further, it is determined whether image data is transmitted in conjunction with the speed of the automobile. During high-speed traveling, there is a possibility that the wireless LAN spot may be lost during the transmission of image data.
[0144]
FIG. 32 is a flowchart showing communication control executed by the in-vehicle computer 201.
In step S4001, it is detected whether it is in a communication standby state. The communication standby state is a state in which data communication is on standby so that data such as image data is automatically transmitted to the outside when communication is possible. If it is in the communication standby state, the process proceeds to step S4002. If it is not in the communication standby state, step S4001 is continued to continue to detect that the communication standby state is entered. In step S4002, the capacity of data waiting for communication is acquired. In step S4003, average travel speed information for the latest 10 minutes of the automobile is acquired. In step S4004, hot spot information that passes next on the travel route by navigation is acquired. In step S4005, it is calculated whether the data capacity is such that the image data waiting for communication when passing through the next hot spot can be transmitted. In step S4006, it is determined from the calculation result whether transmission is possible. If it is determined that transmission is possible, the process proceeds to step S4007. If it is not determined that transmission is possible, the process returns to step S4002.
[0145]
In step S4007, it is detected whether or not transmission has entered the hot spot. If the transmission is enabled, the process proceeds to step S4008. If the transmission is not enabled, the detection is continued. In step S4008, the waiting data is transmitted to an external transmission destination such as a server computer.
[0146]
By controlling as described above, the in-vehicle computer 201 automatically transmits image data sucked from the camera-equipped mobile phone 101 to an external server computer when a vehicle enters a hot spot area provided in a gas station or the like. Yes, there is no need to send after entering the hotspot area.
[0147]
In addition, by controlling in this way, it is possible to prevent encountering a problem such as falling into a communication disabled state during data transmission. Further, instead of transmitting all the image data in one transmission, the image data to be transmitted may be transmitted separately. In addition, although it is calculated whether the data can be transmitted using the average traveling speed of the automobile, it may be calculated based on the current traveling speed instead of the average. The average speed may not be the latest 10 minutes. The image data may be transmitted only when the automobile is stopped (when the traveling speed is 0 km / h).
[0148]
The control described below is to receive a print of the image data that has been ordered for printing when the rental car is returned.
First, the control executed by the in-vehicle computer 201 will be described. FIG. 33 is a flowchart showing the control executed by the in-vehicle computer.
[0149]
In step S5001, the function of the GPS sensor 111 is used to determine whether the distance from the rental car return location is within a predetermined distance. When the rental car store is selected as the navigation destination, the in-vehicle computer 201 determines that the place selected as the destination is the rental car return place. For example, the predetermined distance here is 10 km. If it is within the predetermined distance, the process proceeds to step S5002, and if it is not within the predetermined distance, the determination is continued. In step S5002, it is detected whether or not the rental car is stopped. This is because when not stopped, the display is switched and operated only when the vehicle is stopped to concentrate on driving. If the automobile is stopped, the process proceeds to step S5003. If the automobile is not stopped, the detection is continued.
[0150]
In step S5003, the display on the monitor 107 is switched from the navigation display to the print order candidate image list displayed on the in-vehicle computer 201. FIG. 34 shows a display example of the print order candidate image list display. In FIG. 34, a list of reduced images 304 of image data for which print orders have been placed is displayed. Further, the print size and the number of prints ordered are displayed below the reduced image 304. For example, image 1 is ordered to print one sheet at the service size. Here, a change in print order is accepted. When changing the print order, the all image display button 305 is operated. When the all image display button 305 is operated, the screen moves to a screen for displaying all the transmitted image data, and a print order can be added or corrected. If the contents of the current print order candidate are acceptable, the print order button 306 is operated. When the print order button 306 is operated, a print order is finally made to a laboratory that executes printing, and printing is started in the print laboratory or the like.
[0151]
In step S5004, it is detected whether the print order has been changed by operating the all-image display button 305. If there is a change, the process returns to step S5003, and is displayed again according to the changed content. If there is no change, the process advances to step S5005. In step S5005, it is detected whether or not the print order button 306 has been operated. If it is operated, the process proceeds to step S5006. If it is not operated, the detection is continued. In step S5006, an order signal is transmitted to the print server 301. In addition, return place information set as a destination by navigation is also transmitted to the print server 301. In addition, although it transmitted directly with respect to the print server 301, you may transmit to the print server 301 once through an authentication server like 1st Embodiment.
[0152]
In step S5007, it is detected whether the delivery location confirmation information and the print fee information transmitted by the print server 301 in response to the order signal are received. If received, the process proceeds to step S5008. If not received, the detection is continued. In step S5008, the display on the monitor 107 is switched to a display showing the print price and the print delivery location as shown in FIG. In FIG. 35, the print price is 300 yen and the print receiving place is the store where the rental car is returned. It also displays payment for the print price and the rental car price. Also, in the display example shown in FIG. 35, an inquiry is made as to whether payment for a print fee or a rental car fee is to be made. By operating the settlement button 307, the print price or the rental car price can be settled. Further, by operating the collective settlement button 308, it is possible to settle the print price and the rental car price collectively.
[0153]
In step S5009, it is detected whether the settlement button 307 or the collective settlement button 308 has been operated. If the settlement button has been operated, the process proceeds to step S5010, and if the settlement button has not been operated, the process proceeds to step S5011. In step S5010, a payment process is executed using the payment system of the connected mobile phone. In step S5011, it is determined whether a predetermined time (for example, 1 minute) has elapsed since the display of FIG. If it has elapsed, the process proceeds to step S5012. If it has not elapsed, the display of FIG. 35 is continued. In step S5012, the monitor 107 is switched to the navigation display.
[0154]
Next, control executed by the print server 301 for which a print order has been placed will be described. FIG. 36 is a flowchart showing the control executed by the print server 301.
[0155]
In step S6001, it is detected whether print order information, return place information, and return expected time information have been received. The estimated return time is the estimated arrival time at the destination calculated by the car navigation function. If received, the process proceeds to step S6002, and if not received, reception detection is continued. In step S6002, image data for which a print order has been placed is read. In step S6003, the receiving location information that is the rental car return location and the print fee information are transmitted to the in-vehicle computer 201.
[0156]
In step S6004, a print lab near the rental car return place is searched. In step S6005, the image data and the print order information are transmitted to the computer in the print laboratory near the rental car return location obtained by the search.
[0157]
In step S6006, an expected time required from the start of printing to finishing is calculated. In step S6007, a print start time limit including the delivery time to the rental car return destination from the expected rental car return time is calculated. In step S6008, it is determined whether to start printing immediately compared with other print order information. If printing is to be started immediately, the process proceeds to step S6009. If printing is to be waited for, printing start determination is continued.
[0158]
In step S6009, printing of image data for which a print order has been placed is executed. In step S6010, it is detected whether printing is completed. If it has been completed, the process advances to step S6011, and if it has not been completed, printing is continued. In step S6011, the delivery of the print is arranged at the rental car return destination in time for the user's rental car return time.
[0159]
The above control is processed by the print server 301, but may be processed by another server computer. Further, processing may be performed in cooperation with another server computer instead of one print server.
[0160]
As a result, it is possible to save time such as calculating the print fee after arriving at the return car rental store where the rental car is returned, and the print fee can be easily settled. In addition, it is possible to settle the print fee and the rental car fee together using the camera-equipped mobile phone, so that time is not spent at the rental car return destination. In addition, the print of the image data for which the print order has been placed is delivered to the base where the rental car is returned and can be received simultaneously with the return of the rental car. Also, by confirming the final print order near the rental car return location and executing the print, the prints of the same user can be collectively printed, and there is no burden on the work such as print sorting. In addition, since an image ordered for printing can be canceled, useless printing does not occur.
[0161]
In addition, it automatically urges the last order for the print order, so you never forget the print order. In addition, since the print is started in time for the expected return time of the rental car so that the print can be received when the rental car is returned, the user does not need to wait for the arrival of the print at the rental car return destination.
[0162]
In addition, since a print lab that is close to the rental car return destination (print receiving destination) is automatically selected, it is possible to reduce delivery time loss.
A printer and a print server may be installed in a rental car return location, and image data may be automatically transmitted to the rental car return location and printed by a printer in the store. In addition, the print lab and the rental car store may jointly open a store.
[0163]
In the above control, an example is shown in which the rental car return destination is automatically selected as the print receiving and delivery location. However, if the rental car return destination is not in the print lab's print delivery route, there is a possibility that extra delivery costs will be incurred. Moreover, it is inconvenient when the distance between the rental car return destination and the print lab is long. In such a case, a gas station, convenience store, hotel, or the like on the travel route to the rental car return destination is automatically selected. In some cases, refueling is required before returning the rental car. Therefore, an example in which a gas station on the travel route is used as a print delivery location will be described.
[0164]
FIG. 37 is a flowchart showing the control executed by the in-vehicle computer 201. This flow starts when a print order is detected.
First, in step S6101, a gas station on the travel route is searched. The in-vehicle computer 201 includes a gas station database. The database also includes information such as gas station opening hours, regular holidays, etc., so search is performed considering gas stations that cannot be delivered by date and time. Note that an external gas station database may be accessed.
[0165]
Next, in step S6102, it is determined whether there is a gas station equipped with a print lab among the gas stations hit in the search in step S6101. If it exists, the gas station is selected as an ordering candidate and the process proceeds to step S6105. If it does not exist, the process proceeds to step S6103.
[0166]
In step S6103, it is determined whether there is a gas station that can be printed and delivered among the gas stations that have been hit in the search in step S6101. If it exists, the gas station is selected as an ordering candidate and the process proceeds to step S6105. Otherwise, the process proceeds to step S6104. In step S6104, a print delivery place such as a convenience store other than the gas station is searched.
[0167]
In step S6105, the gas station to which the print is delivered is determined. Here, priority is given from various conditions among the candidate suppliers, and the upper gas station is determined as the delivery gas station. Here, the conditions are, for example, close to the rental car return place with a sufficient print time (far from the current location).
[0168]
In step S6106, the determined estimated arrival time at the gas station and the print order information are transmitted to the print server 301. The print server 301 calculates whether it is possible to deliver the print at the estimated arrival time at the determined gas station. In step S6107, the calculation result is received from the print server 301. In step S6108, it is determined from the calculation result received from the print server 301 whether the print can be delivered. If the print delivery is possible, the process proceeds to step S6109. If the print delivery is not possible, the process returns to step S6105 to determine the next candidate gas station.
[0169]
In step S6109, the print server 301 is ordered. In step S6110, the gas station information is displayed on the monitor 107, and the gas station information is also notified by voice using the speaker 109. In step S6111, the determined gas station is automatically set as a sub destination by the navigation function. The sub destination is a navigation destination that is temporarily set. Navigation does not stop after arriving at the sub-destination, but continues until it arrives at the rental car return destination that is the main destination.
[0170]
In addition, the print server 301 that has received the print order executes control such as print start and delivery to the print laboratory as in FIG.
As a result, the print can be delivered before the rental car is returned and the refueling is completed, so that the automobile is not stopped only for the print delivery.
[0171]
Instead of delivering the print before returning the rental car, a home or a convenience store near the home may be selected as the print delivery location.
Next, control for managing image data stored in the HDD 105 of the in-vehicle computer 201 will be described. If the image data stored in the HDD 105 of the in-vehicle computer 201 is stored in the HDD 105 as it is, the user cannot use it along with the return of the rental car, and is then viewed by the rented user. Control for managing image data executed by the in-vehicle computer 201 in order to prevent such a problem, which is executed by the in-vehicle computer 201, will be described.
[0172]
In order to enable the user to use the image data stored in the HDD 105 of the in-vehicle computer 201 even after returning the rental car, the user is made to select a means for transferring the image data. The means to transfer image data to the user is to move the image data to a designated memory that can be accessed online using the Internet, etc., and to upload the image data to the album server so that the image data can be downloaded later via the Internet A means for attaching the image data to an e-mail, and a means for saving the image data in a take-back memory such as a CD-R. When the control for transferring the image to the user is completed, the image data is automatically completely deleted from the HDD 105 of the in-vehicle computer.
[0173]
38 to 42 are flowcharts showing image management control executed by the in-vehicle computer 201.
First, in step S6021 of FIG. 38, the function of the GPS sensor 111 is used to determine whether the distance from the rental car return location is within a predetermined distance. For example, the predetermined distance here is 2 km. If it is within the predetermined distance, the process proceeds to step S6022. If it is not within the predetermined distance, the determination is continued. In step S6022, a screen for selecting means for transferring image data is displayed on the monitor 107. FIG. 43 shows a display example of the selection screen. In FIG. 43, when the user selects a means for transmitting image data to a designated memory that can be accessed online by using the Internet, the user operates the button 309 to make the album available for downloading. A button 310 is operated to select a means for uploading image data to the server. Further, the button 311 is operated when selecting a means for sending image data attached to an e-mail, and the button 312 is selected when selecting a means for storing image data in a memory that can be taken home such as a CD-R. Manipulate.
[0174]
In step S6023, it is detected whether or not the button 309 has been operated. If it is operated, the process proceeds to step S6024, and if it is not operated, the process proceeds to step S6025. In step S6024, designated destination storage control to be described later is executed. In step S6025, it is detected whether or not the button 310 has been operated. If it is operated, the process proceeds to step S6026. If it is not operated, the process proceeds to step S6027. In step S6026, album control described later is executed. In step S6027, it is detected whether or not the button 311 has been operated. If it is operated, the process proceeds to step S6028, and if it is not operated, the process proceeds to step S6029. In step S6028, mail control described later is executed. In step S6029, it is detected whether or not the button 312 has been operated. If it is operated, the process proceeds to step S6030. If it is not operated, the process returns to step S6023. In step S6028, memory control described later is executed.
[0175]
In step S6031, the monitor 107 displays that image data has been transferred by the selected means. Subsequently, in step S6032, the image data in the HDD 105 is completely erased. Here, erasing image data is an erasing method using a data erasing program, and image data is never restored.
[0176]
Next, the designation destination storage control executed in step S6024 will be described. FIG. 39 is a flowchart showing designated destination storage control executed by the in-vehicle computer 201.
[0177]
First, in step S6041, a screen for allowing the user to input a designated memory address, connection ID, and the like necessary for storing the image data in the online memory is displayed on the monitor 107. In step S6042, it is detected whether an address and a connection ID are input. If it is input, the process proceeds to step S6043. If it is not input, the process returns to step S6041. In step S6043, an attempt is made to connect to the designated address.
[0178]
In step S6044, it is detected whether or not a connection has been made to the designated address. If the connection is successful, the process proceeds to step S6045. If the connection is unsuccessful, the process returns to step S6041 to prompt the input of an accurate address, connection ID, and the like again. In step S6045, the image data stored in the HDD 105 is transmitted to the memory of the connected designated address. Subsequently, in step S6046, it is detected whether or not transmission of all image data has been completed. If the transmission has been completed, this flow is terminated. If the transmission has not been completed, the process returns to step S6045 to continue the transmission of the image data.
[0179]
Next, the album control executed in step S6026 will be described. FIG. 40 is a flowchart showing album control executed by the in-vehicle computer 201.
[0180]
First, in step S6051, connection is made to a predetermined album server. In step S6052, the image data stored in the HDD 105 is uploaded. In step S6053, it is detected whether uploading of image data is completed. If completed, the process proceeds to step S6054. If not completed, the process returns to step S6052 to continue uploading. In step S6054, information such as the album server address, authentication ID, and password required to access the uploaded image data is stored in the memory in the camera-equipped mobile phone 101, and this flow ends.
[0181]
Next, the mail control executed in step S6028 will be described. FIG. 41 is a flowchart showing the mail control executed by the in-vehicle computer 201.
[0182]
First, in step S6061, a screen for allowing the user to input a mail address for transmitting image data is displayed on the monitor 107. In step S6062, it is detected whether an e-mail address has been input. If it is input, the process proceeds to step S6063. If it is not input, the process returns to step S6061.
[0183]
In step S6043, an e-mail attached with image data stored in the HDD 105 is transmitted to the input e-mail address. Subsequently, in step S6064, it is detected whether or not the mail transmission is completed. If the e-mail transmission is completed, this flow is finished. If the e-mail transmission is not completed, there is a high possibility that the input e-mail address has an error. Prompt for a valid email address.
[0184]
Finally, the memory control executed in step S6030 will be described. FIG. 42 is a flowchart showing the memory control executed by the in-vehicle computer 201.
[0185]
First, in step S6071, a screen for prompting the user to install a memory for writing image data and taking it home is displayed on the monitor 107. Succeedingly, in a step S6072, it is detected whether or not a memory is attached. If so, the process proceeds to step S6073. If not, the process returns to step S6071.
[0186]
In step S6073, the image data in the HDD 105 is written in the attached memory. In step S6074, it is detected whether the writing of the image data to the memory is completed. If it has been completed, this flow ends. If it has not been completed, the process returns to step S6073 to continue writing image data into the memory.
[0187]
Thus, by controlling the image data in the HDD 105 of the in-vehicle computer 201 to be delivered to the user, the user can obtain the image data in a ready manner. In addition, it is possible to prevent the image data from being seen by the next rented user.
[0188]
Further, in the above control, the address, authentication ID, password, etc. necessary for accessing the album page are stored in the camera-equipped mobile phone 101, so there is no need to leave a handwritten memo etc. Never forget your address on the album page.
[0189]
As described above, in the second embodiment, the camera system in which the camera-equipped mobile phone 101 owned by the user and the rental car cooperate with each other has been described. Also good. Further, the present invention can be implemented not only in rental cars but also in private cars and commercial vehicles.
[0190]
Further, although an example in which an automobile is used as a rental car has been shown, the camera system of the present invention can be realized even with a vehicle such as a small airplane or a motorcycle, even if it is not a so-called automobile.
[Brief description of the drawings]
FIG. 1 is a functional block diagram illustrating an overview of a camera system according to a first embodiment.
FIG. 2 is a block diagram showing a configuration of a camera-equipped mobile phone 1;
FIG. 3 is a block diagram showing a configuration of the authentication server 3;
FIG. 4 is a block diagram illustrating a configuration of the image storage server 4;
FIG. 5 is a block diagram illustrating a configuration of the print server 5;
FIG. 6 is a flowchart showing the control executed by the CPU 13;
FIG. 7 is a flowchart illustrating control executed by a CPU 31.
FIG. 8 is a flowchart showing the control executed by the CPU 31 of the authentication server 3;
FIG. 9 is a flowchart showing the control executed by the CPU 31 of the authentication server 3;
FIG. 10 is a flowchart showing the control executed by the CPU 41 of the image storage server 4;
FIG. 11 is a flowchart showing the control executed by the CPU 51 of the print server 5;
FIG. 12 is a flowchart showing the control executed by the CPU 51.
FIG. 13 is a flowchart showing the control executed by the CPU 13; It starts when editing work is started on the camera-equipped mobile phone 1.
FIG. 14 is a flowchart showing the control executed by the CPU 41.
FIG. 15 is a flowchart showing control executed by the camera-equipped mobile phone 1;
FIG. 16 is a diagram illustrating a display example immediately after shooting.
FIG. 17 is a block diagram illustrating a camera system according to a second embodiment.
FIG. 18 is a flowchart illustrating image data siphoning control executed by the in-vehicle computer 201.
FIG. 19 is a flowchart showing image processing control executed by the in-vehicle computer 201.
FIG. 20 is a flowchart showing the control executed by the in-vehicle computer 201.
FIG. 21 is a diagram illustrating an example of a screen displayed on the monitor 107;
FIG. 22 is a diagram illustrating an example of an image list display displayed on the monitor 107;
FIG. 23 is a flowchart showing the control executed by the in-vehicle computer 201.
FIG. 24 is a flowchart showing the control executed by the in-vehicle computer 201.
FIG. 25 is a flowchart showing the control executed by the in-vehicle computer 201.
FIG. 26 is a flowchart showing call control executed by the in-vehicle computer 201.
FIG. 27 is a flowchart showing the control executed by the in-vehicle computer 201.
FIG. 28 is a diagram illustrating a display example of a navigation screen.
FIG. 29 is a flowchart showing travel route calculation control executed by the in-vehicle computer 201.
FIG. 30 is a display example showing travel route information in the hot spot mode.
FIG. 31 is a flowchart showing travel route calculation control executed by the in-vehicle computer 201.
FIG. 32 is a flowchart showing communication control executed by the in-vehicle computer 201.
FIG. 33 is a flowchart showing the control executed by the in-vehicle computer.
FIG. 34 is a diagram illustrating a display example of print order contents.
FIG. 35 is a diagram illustrating a display example of receiving location information, a print fee, and the like.
FIG. 36 is a flowchart showing control executed by the print server 301. FIG.
FIG. 37 is a flowchart showing the control executed by the in-vehicle computer 201.
FIG. 38 is a flowchart showing image management control executed by the in-vehicle computer 201.
FIG. 39 is a flowchart showing designated destination storage control executed by the in-vehicle computer 201.
FIG. 40 is a flowchart showing album control executed by the in-vehicle computer 201.
41 is a flowchart showing mail control executed by the in-vehicle computer 201. FIG.
42 is a flowchart showing memory control executed by the in-vehicle computer 201. FIG.
FIG. 43 is a diagram illustrating a display example of a selection screen.
[Explanation of symbols]
1, 101 ... Mobile phone with camera
2, 8 ... Provider
3. Authentication server
4. Image storage server
5, 301 ... print server
6 ... Printer
7 ... PC
11 ... Image sensor
12. Image processing circuit
13, 31, 41, 51, 104 ... CPU
14 ... Built-in memory
15 ... Card slot
16 ... Shutter button
17, 107 ... monitor
18, 35, 43, 54, 103 ... communication circuit
32 ... Customer database
33 ... Lab database
34 ... Program memory
42. Image storage memory
52. Print program storage unit
53. Image optimization program storage unit
55, 105 ... Hard disk drive
201 ... In-vehicle computer
102 ... Cradle
106: Display circuit
108 ... Microphone
109 ... Speaker
110 ... Controller
111 ... GPS

Claims (16)

Communication means for transmitting captured image data to an external device;
During a predetermined period after shooting, a deletion unit that can delete the last captured image data by a specific operation, and a waiting period for transmission of the image data by the communication unit during a predetermined period that can be deleted by the deletion unit. A digital camera, wherein the image data is transmitted to an external device after completion. The digital camera according to claim 1, further comprising display means.
The digital camera characterized in that the last imaged image data is displayed on the display means during the predetermined period. 3. The digital camera according to claim 2, wherein the display means performs a display prompting a deletion operation together with the image data captured last during the predetermined period. 2. The digital camera according to claim 1, wherein the image data transmitted to the external device by the communication means is RAW image data. Communication means for transmitting photographed image data to an external device, image processing means for performing optimization processing on the image data, and instruction means for instructing image data to be transmitted to the external device using the communication means An image processing apparatus comprising: control means for controlling the image data instructed to be transmitted to the external apparatus by the instruction means to be optimized by the image processing means. 6. The image processing apparatus according to claim 5, wherein the instruction unit instructs the image data for which print ordering has been placed. The image processing apparatus according to claim 5, further comprising an acquisition unit configured to acquire captured camera information, wherein the optimization process performs an optimization process on image data based on the camera information. Image processing device. 8. The image processing apparatus according to claim 7, wherein the camera information is aberration information of a photographing lens. The image processing apparatus according to claim 5, wherein the image data is RAW image data. Communication means for transmitting photographed image data to an external device, image processing means for performing optimization processing on the image data, and instruction means for instructing image data to be transmitted to the external device using the communication means And control means for controlling the image processing means to perform optimization processing on the image data excluding the image data instructed to be transmitted to the external device by the instruction means. An image processing apparatus. The image processing apparatus according to claim 10, wherein the external apparatus includes a second image processing unit that performs an optimization process on the image data. Receiving means for receiving image data from a digital camera, image processing means for performing optimization processing on the image data received by the receiving means, and image data subjected to optimization processing by the image processing means for the digital camera An image processing apparatus comprising: a transmission unit that automatically transmits data to the image processing apparatus. 13. The image processing apparatus according to claim 12, further comprising acquisition means for acquiring captured camera information, wherein the optimization process performs an optimization process on image data based on the camera information. Image processing device. The image processing apparatus according to claim 13, wherein the camera information is aberration information of a photographing lens. The image processing apparatus according to claim 12, wherein the image data is RAW image data. 13. The image processing apparatus according to claim 12, further comprising: an identification unit that identifies a file format of the received image data. An image processing apparatus characterized by performing an image processing.

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