JP2006050323A - Image browsing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To switch display images without requesting a user troublesome operation in a system for browsing an image picked up by a network camera at a portable telephone terminal connected via a network. <P>SOLUTION: At a step S1, the portable telephone terminal displays an image A1 to a display part. In parallel to the step S1, an image acquisition program is executed according to a specified schedule and a connection between the network camera 1 and an HTTP is established (step S2). Next, in parallel to the step S1, the image acquisition program acquires an image A2 from the network camera 1 (step S3). Then, a CPU of the portable telephone terminal switches the image A1 to the image A2 displayed to the display part. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technique for acquiring and displaying an image captured by a camera via a network in a terminal such as a mobile phone.

  A device called a network camera or a WEB camera has an image pickup sensor and a WEB server function and a network function, and image data picked up by the image pickup sensor can be distributed to various terminals via a network such as the Internet. Yes.

  On the other hand, current mobile phone terminals have a network function and a color image display function, and are increasingly used as multimedia terminals.

  Therefore, as shown in Non-Patent Document 1 below, there is a service that enables browsing of images distributed by a network camera using a mobile phone terminal.

Matsushita Electric Industrial Co., Ltd., “Home network-related products”, [searched July 30, 2004], Internet <URL http://panasonic.co.jp/pcc/products/hnetwk/support/technic/mbl_phn_list-c10.html>

  In a service that distributes an image captured by a network camera to a terminal such as a mobile phone, including the service described in Non-Patent Document 1, the user of the mobile phone terminal operates the “Update” button to update the image. There is a need. The number of images that can be acquired in response to the “update” button operation by the user is one image. Therefore, it is necessary to operate the “update” button every time a new image is browsed, which is inconvenient.

  Here, as a method of automatically updating an image, a method of performing a refresh function is conceivable. However, a refresh function in HTML may be limited depending on a terminal such as a mobile phone, and the image is updated in these terminals. After all, it is necessary to operate the “update” button and the like.

  In HTTP, each time an object is transferred, the HTTP connection is disconnected. For this reason, in order to acquire a new image, it is necessary to connect the HTTP connection again, which causes a delay in the time from when the user operates the “update” button until the next image is displayed. It was.

  Further, in a PC or the like, an image distributed by a network camera can be reproduced as a moving image. This is because a sufficient buffer memory may be secured in a PC or the like. Or it is because it is possible to use an application on UDP in a PC or the like. On the other hand, depending on a terminal such as a mobile phone, an application operating on UDP may not be permitted. Even when an application that operates on HTTP is used, the maximum communication buffer size is severely limited, and it is difficult to reproduce a moving image as it is.

  Therefore, the present invention provides a technique that enables a new image to be browsed without requiring a complicated operation in a method for browsing an image distributed by a network camera. It is another object of the present invention to provide a technique that enables browsing of moving images as well as still images.

  In order to solve the above-mentioned problem, the invention according to claim 1 is a method of browsing an image acquired via a network, and the browsing terminal operates a program incorporated in the browsing terminal to operate the network. A first step of acquiring a first image from the image capturing device via the second step, a second step in which the browsing terminal displays the first image on a display device of the browsing terminal, and the second step. In parallel, a third process in which the browsing terminal executes a connection process with the image capturing device by the program operating according to a set schedule, in parallel with the second process, A fourth step in which the browsing terminal acquires a second image from the image pickup device by the operation of the program, and display contents for the display device from the first image to the second Characterized in that it comprises a fifth step of switching to image.

  According to a second aspect of the present invention, in the image browsing method according to the first aspect, the program is a program that operates on HTTP, and the connection process is a connection establishment process in HTTP.

  According to a third aspect of the present invention, in the image browsing method according to the first or second aspect of the present invention, the display is currently performed when the browsing terminal inputs a save instruction from an operation input unit of the browsing terminal. Storing an image displayed on the apparatus in a storage device.

  The invention according to claim 4 is a method of browsing an image acquired via a network from an image pickup device that always picks up an image at a predetermined frame rate, wherein the browsing terminal stores a program incorporated in the browsing terminal. A first step of acquiring N frames of images stored in the image capturing apparatus via a network by operating the display, and the browsing terminal displays the images of the N frames as a moving image; In parallel with the second step of displaying on the device and the second step, the program operates according to a set schedule, whereby the browsing terminal executes a connection process with the image capturing device. In parallel with the third step and the second step, a new N stored in the image capturing device is stored in the browsing terminal by the operation of the program. A fourth step of acquiring an image of frame content, the viewing terminal is characterized in that it comprises a fifth step of displaying on said display device a new N frames images of the as video.

  According to a fifth aspect of the present invention, in the image browsing method according to the fourth aspect, the images for the N frames are images having a maximum number of frames within a range not exceeding a maximum communication buffer size of the program. To do.

  According to a sixth aspect of the present invention, in the image browsing method according to the fourth aspect, the number N of frames of an image acquired by the browsing terminal in one step is dynamically changed.

  According to a seventh aspect of the present invention, in the image browsing method according to any one of the fourth to sixth aspects, the second step is still after the fourth frame of moving image display is finished, the fourth step. In the case where the above step is not completed, a step of continuously displaying the image of the last frame is included.

  According to an eighth aspect of the present invention, in the image browsing method according to any of the fourth to seventh aspects, after the moving image display for the N frames is completed, the fourth step has not been completed yet. In some cases, the method includes a step of displaying a message indicating that an image is being acquired on the display device.

  The invention according to claim 9 is the image browsing method according to any one of claims 4 to 8, wherein the program is a program operating on HTTP, and the connection process is a connection establishment process in HTTP. It is characterized by being.

  According to a tenth aspect of the present invention, in the image browsing method according to any one of the fourth to ninth aspects, the browsing terminal further inputs a save instruction from an operation input unit provided in the browsing terminal. Storing a frame image currently displayed on the display device as a still image in a storage device.

  The invention according to claim 11 is a method in which an image capturing apparatus that continuously captures an image at a predetermined frame rate distributes an image via a network, and the image capturing apparatus stores a predetermined number of stored images. A first step of distributing an image of N frames selected according to an algorithm, and the image pickup device is selected according to the algorithm from among accumulated images after a time set from the first step And a second step of distributing images for new N frames.

  According to a twelfth aspect of the present invention, in the image browsing method according to the eleventh aspect, the images for N frames are images having a maximum number of frames in a range not exceeding a maximum communication buffer size of the program. To do.

  The present invention executes a connection process from the terminal to the image capturing apparatus in parallel with the process of displaying the first image on the display device of the terminal, and further acquires the second image. Thereby, the user does not need to operate the update button or the like, and the display image is automatically switched, which is convenient.

  In addition, the present invention executes a connection process from the terminal to the image capturing apparatus in parallel with the process of displaying a moving image on the terminal using a plurality of images acquired from the image capturing apparatus, and further includes a plurality of images. Get the. As a result, even in a system that is restricted by hardware resources or restricted by a communication protocol, it is possible to display a moving image on a terminal in a pseudo manner.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an overall view of an image browsing system according to an embodiment of the present invention. The network camera 1 is a device having an image capturing function, a network connection function, and a WEB server function, and is generally a device also called a WEB camera. The mobile phone terminal 5 has a network connection function in addition to a voice call function as a basic function of the mobile phone. The network camera 1 is connected to the Internet 2, the mobile phone terminal 5 is connected to the mobile phone network 3 via the base station 4, and the Internet 2 and the mobile phone network 3 are further connected. The network camera 1 and the mobile phone terminal 5 can communicate with each other.

  In such a system configuration, the network camera 1 distributes captured images to various terminals using a WEB server function. That is, the network camera 1 can distribute captured images to terminals connected to the Internet 2 and various terminals connected to various networks connected via the Internet 2. The mobile phone terminal 5 has a web content browsing function, and can browse images distributed by the network camera 1.

<First Embodiment>
Next, a first embodiment of the present invention will be described with reference to FIGS.

  FIG. 2 is a block diagram of the network camera 1. The network camera 1 includes an image sensor 11, an image processing unit 12, a communication unit 13, a memory 14, and a CPU 15. The image sensor 11 includes an optical lens, a CCD image sensor, and the like, and can capture a subject image. The image data output from the image sensor 11 is subjected to various types of image processing in the image processing unit 12. The CPU 15 executes various programs stored in the memory 14. The memory 14 stores a WEB server program (not shown), and the CPU 15 can implement the WEB server function in the network camera 1 by executing the WEB server program. The communication unit 13 has a function of transmitting / receiving data to / from the Internet 2.

  FIG. 3 is a block diagram of the mobile phone terminal 5. The cellular phone terminal 5 includes an antenna 51, a communication unit 52, a CPU 53, a memory 54, an operation unit 55, and a display unit 56. The communication unit 52 has a function of transmitting / receiving data to / from the base station 4 via the antenna 51. The communication unit 52 includes a buffer memory 57 and a function of temporarily storing received data. The CPU 53 executes various programs stored in the memory 54. The memory 54 stores a WEB browser program (not shown), and the CPU 53 can browse WEB content by executing the WEB browser program.

  The memory 54 stores an image acquisition program 61. The image acquisition program 61 is a program that operates on HTTP, and for example, a JAVA (R) application program can be used. As a specific example, a program called i-appli for a mobile phone made by NTT Docomo and an EZ app for a mobile phone made by au correspond.

  The operation unit 55 includes operation buttons for executing various functions of the mobile phone terminal 5, a cross cursor, and the like. By operating the operation unit 55, the user can perform input operations of various characters such as a telephone number and an e-mail address, a process of connecting to a network, a browsing operation of WEB contents, and the like. The display unit 56 includes an LCD or the like, and displays WEB content. The display unit 56 is used for displaying telephone numbers and mails.

  FIG. 4 is a diagram showing a flow of processing for browsing an image distributed by the network camera 1 in the mobile phone terminal 5. In this embodiment, the mobile phone terminal 5 displays an image captured by the network camera 1 as a still image.

  In FIG. 4, step S <b> 1 is a step in which an image A <b> 1 is displayed on the display unit 56 of the mobile phone terminal 5. Specifically, this step S 1 is a step in which the WEB browser program operating on the CPU 53 displays the image A 1 stored in the memory 54. The user can browse the image A1 by referring to the display unit 56.

  Step S2 is a step in which the cellular phone terminal 5 establishes an HTTP connection with the network camera 1, and is a step executed in parallel with step S1. That is, step S2 is a step executed in parallel in the background while the image A1 is being displayed.

  When the HTTP connection is established, next, the mobile phone terminal 5 acquires the image A2 from the network camera 1 in step S3.

  Steps S2 and S3 are steps in which the image acquisition program 61 is executed according to a set schedule. For example, if it is assumed that the time for which one still image is to be displayed on the display unit 56 is T1, and the time required for HTTP connection processing and image acquisition processing is T2, the disclosure time in step S1 is used. (T1-T2) Step S2 may be started after the lapse of time. In the image acquisition program 61, a schedule assuming such times T1 and T2 is set as a default setting. However, these schedules can be freely changed by the user.

  When step S3 ends and acquisition of the image A2 is completed, in step S4, the mobile phone terminal 5 switches the display content on the display unit 56 from the image A1 to the image A2. That is, when the image acquisition program 61 acquires the image A2, the WEB browser program switches the display image from the image A1 to the image A2.

  Further, in parallel with step S4, an HTTP connection is established between the mobile phone terminal 5 and the network camera 1 in step S5, and the next image A3 is acquired in step S6. In this way, every time an image is acquired, an HTTP connection establishment process is performed.

  When step S6 ends and acquisition of the image A3 is completed, in step S7, the mobile phone terminal 5 switches the display content on the display unit 56 from the image A2 to the image A3. Similarly, Step 8 and Step 9 are executed in parallel with Step S7, and the image A4 is acquired.

  As described above, in the present embodiment, the image acquisition program 61 automatically starts operating in the background while an image is displayed on the display unit 56 of the mobile phone terminal 5, and the network camera 1 Since the connection process and the image acquisition process are executed in the meantime, the user of the mobile phone terminal 5 does not need to perform an operation for updating the image in order to view a new image.

  In addition, since an operation for acquiring the next image is performed while a certain image is displayed, it is possible to shorten the time until the image is displayed. Thereby, for example, a still image can be switched and displayed every 1 to 3 seconds.

  For example, a WEB function that can be used in a mobile phone terminal may be limited to a refresh function that automatically updates WEB content. Even in such a case, according to the present invention, an image is automatically displayed. It can be updated. Further, even when using a protocol such as HTTP in which disconnection processing is performed each time an object is transmitted, according to the present invention, connection processing is performed in the background during image display. Therefore, it is possible to shorten the time until image display.

  Next, an additional function of the image browsing system according to the first embodiment will be described. As described above, still images are sequentially switched and displayed on the display unit 56 of the mobile phone terminal 5. During the display of the still image, the user can input an image saving instruction by operating the operation unit 55. When the image saving instruction is input, the CPU 53 stores the image currently displayed on the display unit 56 in the memory 54 for saving. As a result, the user can browse through the images that are sequentially switched and store the images immediately upon finding a favorite image.

  In order to realize such a function, an operation button for instructing image storage is associated with one of the operation buttons on the operation unit 55, and the position of the associated operation button is displayed on the display unit 56. This is convenient. For example, if an operation button for instructing image storage is displayed on the display unit 56 with a title such as “snap”, it is convenient.

<Second Embodiment>
Next, a second embodiment of the present invention will be described with reference to FIGS. In the first embodiment, the mobile phone terminal 5 switches and displays still images. However, in this embodiment, the mobile phone terminal 5 continuously displays a plurality of images.

  FIG. 5 is a block diagram of the network camera 1. This network camera 1 has the same configuration as that of the network camera 1 in the first embodiment. The difference is that the imaging sensor 11 always performs an imaging operation at a predetermined frame rate, and sequentially stores the captured images in the memory 14. Therefore, the memory 14 in the first embodiment does not need a large area in addition to the area for storing the program, but the memory 14 in the second embodiment has a buffer for storing a plurality of frame images. The difference is that it requires an area. As shown in the figure, in this embodiment, M (M is an integer) images B1, B2,... BM are stored in the memory. However, the number of image frames that can be stored varies depending on the frame rate and resolution.

  The imaging sensor 11 always performs an imaging operation, and the image data output from the imaging sensor 11 is sequentially subjected to image processing in the image processing unit 12 and is sequentially stored in the memory 14. The memory 14 is configured, for example, as a ring buffer. When a new image is stored, the oldest image is deleted, so that the latest M images B1, B2, and B are always stored. ... BM is accumulated.

  FIG. 6 is a block diagram of the mobile phone terminal 5. This mobile phone terminal 5 also has the same configuration as the mobile phone terminal 5 in the first embodiment. The difference is that the mobile phone terminal 5 acquires a plurality of images at a time from the network camera 1 and reproduces the plurality of images as moving images, so that the buffer memory 57 and the memory 54 of the communication unit 52 are also This is a point that requires a larger size compared to the first embodiment. Here, the memory 54 can buffer K images, and the CPU 53 reproduces the images C1 to CK buffered in the memory 54 as moving images (the images C1 to CK are network cameras). 1 is one of the stored images B1 to BM).

  That is, the image received from the network camera 1 is temporarily stored in the buffer memory 57 of the communication unit 52, and when an empty area occurs in the buffer area of the memory 54, the image is transferred from the buffer memory 57 to the memory 54 and played back. It is. The buffer area of the memory 54 performs the same function as the ring buffer. That is, when a new frame image is input, the old frame image is deleted in order. Therefore, the occurrence of an empty area in the buffer area indicates that the reproduction of the frame image stored in the buffer area is finished and the erasable state is reached.

  FIG. 7 is a diagram showing a flow of processing for browsing an image distributed by the network camera 1 in the mobile phone terminal 5. In this embodiment, the mobile phone terminal 5 displays an image captured by the network camera 1 as a pseudo moving image.

  In FIG. 7, step S <b> 11 is a step in which images B <b> 1 to BN are continuously displayed as moving images on the display unit 56 of the mobile phone terminal 5. That is, the N images B1 to BN received from the network camera 1 are stored as images C1 to CK in the buffer area of the memory 54 via the buffer memory 57, and are executed by the WEB browser and other programs operating on the CPU 53. These images are displayed on the display unit 56 as moving images. The user can browse the images B <b> 1 to BN as moving images by referring to the display unit 56.

  Step S12 is a step in which the mobile phone terminal 5 establishes an HTTP connection with the network camera 1, and is a step executed in parallel with step S11. That is, step S12 is a step executed in parallel in the background while displaying a moving image.

  When the HTTP connection is established, next, in step S <b> 13, the mobile phone terminal 5 acquires new images B <b> 1 to BN from the network camera 1. The acquired images B1 to BN are stored in the buffer memory 57 of the communication unit 57 and then transferred to the memory 54.

  Here, as described above, the network camera 1 always captures images and accumulates the latest M images B <b> 1 to BM in the memory 14. The image acquisition program 61 is a program that operates on HTTP, and a maximum communication buffer size is defined for one data transfer. Therefore, in step S13, the maximum number of images not exceeding the maximum communication buffer size is transferred. Here, it is assumed that N (N is an integer not exceeding M) images is the maximum number of images not exceeding the maximum communication buffer size. Therefore, the network camera 1 transmits the latest N images from the M images stored in the memory 14 to the mobile phone terminal 5.

  Steps S12 and S13 are steps in which the image acquisition program 61 is executed according to a set schedule. For example, when the time for displaying N moving images is assumed to be T3 and the time required for HTTP connection processing and image acquisition processing is assumed to be T4, (T3-T4) time elapses from the disclosure time in step S11 Step S12 may be started later. In the image acquisition program 61, a schedule assuming such times T3 and T4 is set as a default setting. However, these schedules can be freely changed by the user.

  When step S13 ends and acquisition of new images B1 to BN is completed, in step S14, the mobile phone terminal 5 displays the newly acquired images B1 to BN as moving images on the display unit 56. That is, the WEB browser and other programs operating on the CPU 53 display the images C1 to CK stored in the memory 54 via the buffer memory 57 on the display unit 56 as moving images.

  Further, in parallel with step S14, an HTTP connection is established between the mobile phone terminal 5 and the network camera 1 in step S15, and new images B1 to BN are acquired in step S16. Thus, every time an image is acquired, the HTTP connection establishment process is performed, and new images B1 to BN are sequentially acquired.

  As described above, in the present embodiment, the image acquisition program 61 automatically starts operating in the background in a state where a moving image is displayed on the display unit 56 of the mobile phone terminal 5. Since the connection process and the image acquisition process are executed between the two, the user of the mobile phone terminal 5 does not need to perform an operation for updating the image in order to view a new moving image. Since a plurality of images are acquired at one transfer timing, it is possible to reduce the number of HTTP connections and improve the reproduction speed.

  In addition, since an operation for acquiring the next image is performed while a certain moving image is displayed, it is possible to shorten the time until a new moving image is displayed. In addition, since the network camera 1 always captures and stores images, when receiving an image acquisition request from the mobile phone terminal 5, it is possible to immediately deliver the image and improve the image transfer speed. It is possible to make it.

  In the present embodiment, a plurality of images are acquired and displayed by the WEB browser and an image acquisition program (for example, JAVA (R) application) that operates on the WEB browser. It is possible to reproduce a moving image in a simulated manner even in an environment where a reproduction application does not operate.

  However, in general, the time for acquiring N images is longer than the time for displaying moving images using N images. This is affected by the bandwidth of the communication line, but if the communication is performed using a mobile phone terminal as in the present embodiment, the time required for the image transfer speed becomes long.

  That is, it is assumed that step S13 is not completed when step S11 is completed. Therefore, it is effective to perform a method as shown in FIG. In step S11, after the moving image display for the images B1 to BN ends, the image BN that is the last frame is continuously displayed until step S13 ends. Further, while the last frame is continuously displayed, a message indicating that an image is being acquired is displayed on the display unit 56. For example, messages such as “NOW LOADING” and “acquiring image” are displayed on the display unit 56.

  By adopting such a method, after the moving image is displayed, the still image state continues for a while and the moving image can be continuously displayed. Therefore, the user can simulate the moving image using the mobile phone terminal 5. Can be viewed. For example, it is possible to display a moving image of about 3 frames / second, display a still image for a while, and then display a moving image of about 3 frames / second again. Further, since a message indicating that the image is being acquired is displayed during the still image display, the user is not misunderstood.

  The moving image performance (fps) indicating the moving image playback speed in the mobile phone terminal 5 is correlated with the wait time for image acquisition, and it is possible to improve the moving image performance if the weight is frequently generated. . For example, instead of lengthening the wait time, the moving image may be played back at about 5 frames / second.

  Next, an additional function of the image browsing system according to the second embodiment will be described. As described above, a moving image is displayed on the display unit 56 of the mobile phone terminal 5. During the display of the moving image, the user can input an image saving instruction by operating the operation unit 55. When the image saving instruction is input, the CPU 53 stores the frame image currently displayed on the display unit 56 in the memory 54 as a still image. Thereby, the user can save the frame image immediately when he / she finds a favorite scene while browsing the moving image.

  In order to realize such a function, an operation button for instructing image storage is associated with one of the operation buttons on the operation unit 55, and the position of the associated operation button is displayed on the display unit 56. This is convenient. For example, if an operation button for instructing image storage is displayed on the display unit 56 with a title such as “snap”, it is convenient.

<Modification of Second Embodiment>
As described above, since it takes a long time to acquire an image as compared with the process of displaying a moving image, it is effective to use the method shown in FIG. 8, but conversely the communication speed is very high. If it is very fast, the following method may be used. As described above, the CPU 53 sequentially reproduces the images C1 to CK stored in the buffer area of the memory 54. However, when the communication speed is very high, the speed buffered in the buffer memory 57 is the moving image. When the playback speed is faster than the above, there is not enough free space in the buffer area of the memory 54. Therefore, in such a case, the process of acquiring an image by communication is temporarily stopped. When an empty area is created in the buffer area of the memory 54, the data stored in the buffer memory 57 is transferred to the memory 54 and communication is resumed. By performing such processing, it is possible to reproduce a moving image without interruption on the viewing terminal.

  Further, as described above, in this embodiment, an image that does not exceed the maximum communication buffer size that can be transferred by the image acquisition program 61 is transferred in one transfer. Here, the maximum communication buffer size that can be transferred by the image acquisition program 61 corresponds to a data size that can be transferred in one data transfer in HTTP. However, even if the maximum communication buffer size is 150 KB and an image for 150 KB is transmitted from the network camera 1 in one transfer, if the bandwidth of the communication network is very narrow, the maximum communication buffer size is met. Performance is not obtained. In such a case, it is preferable to reduce the amount of data transferred once from the network camera 1 to the mobile phone terminal 5. Therefore, in the present invention, the mobile phone terminal 5 can dynamically change the maximum communication buffer size. The mechanism for changing the maximum communication buffer size may be automatically changed according to the traffic situation of the network, or may be set manually by the user.

  The process for changing the maximum communication buffer size may be controlled from the mobile phone terminal 5 side or from the network camera 1 side.

<Modification 1>
In the first embodiment and the second embodiment described above, the image acquisition program 61 has been described as operating on HTTP. However, the protocol in which the image acquisition program 61 operates in the present invention is not particularly limited, and HTTP is an example. Of course, the present invention can also be applied to other protocols and proprietary protocols of mobile phone carriers. Even in the case of these other protocols, the connection processing of the protocol is executed in the background while a still image is displayed or a moving image is played, and the image acquisition program 61 operates on the protocol to create a new image. Should be obtained. For example, the present invention can be applied to a program called BREW that operates on a mobile phone of au.

<Modification 2>
In the second embodiment, the network camera 1 receives a request for image acquisition from the mobile phone terminal 5 and transmits a plurality of images. On the other hand, the network camera 1 may transmit an image according to a predetermined schedule without using the acquisition request from the mobile phone terminal 5 as a trigger. Also in this case, the network camera 1 may transmit the maximum number of images within a range not exceeding the maximum communication buffer size of the destination terminal.

  As for this transmission timing, for example, the times T3 and T4 as described above may be registered in advance as default values, or information specifying the transmission schedule may be received from the mobile phone terminal 5 only once at the beginning. Good.

  In this case, which frame of images to transmit among a plurality of images stored in the network camera 1 may be determined according to a set algorithm. For example, the latest N-frame image may be transmitted among a plurality of stored images, or the last frame number of the previously transmitted frame is recorded and the subsequent N-frame image is recorded. May be used. Alternatively, a plurality of algorithms may be prepared so as to be selectable, and an instruction for selecting an algorithm may be sent from the mobile phone terminal 5.

1 is an overall view of an image distribution system. It is a block diagram of the network camera concerning a 1st embodiment. 1 is a block diagram of a mobile phone terminal according to a first embodiment. FIG. It is a figure which shows the processing flow concerning 1st Embodiment. It is a block diagram of the network camera concerning a 2nd embodiment. It is a block diagram of the mobile telephone terminal concerning 2nd Embodiment. It is a figure which shows the processing flow concerning 2nd Embodiment. It is a figure which shows the processing flow which displays a still image after the display of a moving image is complete | finished.

Explanation of symbols

1 Network Camera 2 Internet 3 Mobile Phone Network 4 Base Station 5 Mobile Phone Terminal

Claims (12)

A method for browsing images acquired via a network,
A first step of acquiring a first image from an image capturing device via a network by operating a program incorporated in the browsing terminal;
A second step in which the browsing terminal displays the first image on a display device of the browsing terminal;
In parallel with the second step, a third step in which the browsing terminal executes a connection process with the image capturing device by the program operating according to a set schedule,
In parallel with the second step, a fourth step in which the browsing terminal acquires a second image from the image capturing device by the operation of the program;
A fifth step of switching display content on the display device from the first image to the second image;
An image browsing method comprising the steps of: The image browsing method according to claim 1,
The image browsing method, wherein the program is a program that operates on HTTP, and the connection process is a connection establishment process in HTTP. The image browsing method according to claim 1, further comprising:
The browsing terminal stores an image currently displayed on the display device in a storage device by inputting a save instruction from an operation input unit included in the browsing terminal;
An image browsing method comprising the steps of: A method of browsing an image acquired via a network from an image capturing device that always captures an image at a predetermined frame rate,
A first step of acquiring images for N frames stored in the imaging device via a network by operating a program incorporated in the browsing terminal by the browsing terminal;
A second step in which the browsing terminal displays an image of the N frames as a moving image on a display device of the browsing terminal;
In parallel with the second step, a third step in which the browsing terminal executes a connection process with the image capturing device by the program operating according to a set schedule,
In parallel with the second step, a fourth step in which the browsing terminal acquires images for new N frames accumulated in the image pickup device by the operation of the program;
A fifth step in which the browsing terminal displays the image for the new N frames as a moving image on the display device;
An image browsing method comprising the steps of: The image browsing method according to claim 4,
The image browsing method according to claim 1, wherein the images for N frames are images having a maximum number of frames within a range not exceeding a maximum communication buffer size of the program. The image browsing method according to claim 4,
An image browsing method, wherein the number N of frames of an image acquired by the browsing terminal in one step is dynamically changed. The image browsing method according to any one of claims 4 to 6,
The second step includes
A step of continuously displaying the image of the last frame if the fourth step has not been completed after the N frames of moving image display have been completed;
The image browsing method characterized by including. The image browsing method according to any one of claims 4 to 7,
A step of displaying a message indicating that an image is being acquired on the display device if the fourth step has not been completed after the N frames of moving image display have been completed;
The image browsing method characterized by including. The image browsing method according to any one of claims 4 to 8,
The image browsing method, wherein the program is a program that operates on HTTP, and the connection process is a connection establishment process in HTTP. The image browsing method according to any one of claims 4 to 9, further comprising:
The browsing terminal stores a frame image currently displayed on the display device in a storage device as a still image by inputting a save instruction from an operation input unit included in the browsing terminal;
An image browsing method comprising the steps of: An image capturing apparatus that continuously captures an image at a predetermined frame rate distributes an image via a network,
A first step in which the image pickup device distributes N frames of images selected according to a predetermined algorithm among stored images;
A second step in which the image capturing device distributes an image for a new N frames selected according to the algorithm from among the stored images after the time set from the first step;
An image browsing method comprising the steps of: The image browsing method according to claim 11,
The image browsing method according to claim 1, wherein the images for N frames are images having a maximum number of frames within a range not exceeding a maximum communication buffer size of the program.

Images