JP2007049230A - Video downloading system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video downloading system in which a series of a plurality of video files downloaded from a server can be reproduced with no blank time. <P>SOLUTION: For an access from a user terminal, a video inserter 590 actuates a plurality of virtual video players 591 and 593 and prepares transmission buffers 592 and 594 corresponding to them. A series of a plurality of video files are read out from a media storage 560 and these virtual video players are executed sequentially to write the video files sequentially from a corresponding transmission buffer into a transmission buffer 595 with no blank time between the video files and then the video files are transmitted to a user terminal. The video player 556 of a server terminal can reproduce the plurality of video files with no blank time. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a video distribution system that transmits a moving image from a server.

  With the spread of high-speed Internet connection services such as ADSL and optical fiber, it is expected that demand will increase for services that deliver content such as video programs (videos) on-demand to terminals such as personal computers on the Internet. In fact, such services are being tried.

<Conventional video distribution system and its problems>
A configuration example of a conventional on-demand video distribution system using the Internet is shown in FIG.
Each user receives video distribution via the Internet 140 using a user terminal 150 such as a personal computer.
Here, in the case of a large-scale distribution system, a large load is applied by a large number of users accessing simultaneously, and it cannot be physically processed by one video server 120. For this reason, load distribution is performed using, for example, an L4 (Level 4) switch 130. That is, users are equally distributed to a plurality of video servers 120 to reduce the load per video server. Further, the video files are stored in the common media storage 110 so that the plurality of video servers 120 can read the video files for distribution (video data such as MPEG and AVI) in common.
With such a system configuration, video distribution can be performed without any problem even when many users access simultaneously.

In such a video distribution system, when a separate advertisement video is inserted into a program and distributed for each user, there is a problem that the cost for creating the distribution video becomes enormous. In other words, the conventional on-demand video distribution system is a mechanism in which distribution video is stored in the media storage 110 in advance and distributed in response to a distribution request from the user. In the case of distribution, it is necessary to create a plurality of distribution videos including different advertisements in advance for one program and store them in the media storage 110. However, this method is not practical because the production cost of the video, the cost and time for replacing the advertisement, and the capacity of the media storage 110 become enormous.
On the other hand, as means for solving this problem, video distribution based on a movie list method that continuously distributes a plurality of videos has been proposed. In the movie list method, when an advertisement is inserted between programs, the video of the program is divided into a plurality of video files and stored in the media storage 110 in advance, and the video file and the advertisement video file are alternately displayed by the user. Delivered to the terminal 150. Thereby, it is possible to distribute different advertisement videos for each user or to easily replace advertisements.

<Conventional movie list method and its problems>
A mechanism for continuously delivering a plurality of video files using the conventional movie list method in the conventional video distribution system shown in FIG. 1 will be described with reference to FIGS.
FIG. 2 is a block diagram when a conventional movie list system is used in a conventional video distribution system. The left side of the Internet 140 shows each device of the server, and the right side shows each device of the user terminal. Here, in order to sequentially distribute a plurality of main video files and advertisement video files constituting one program to the user terminal and reproduce them sequentially by the video player 156, the server and the user are required from the start of distribution of the program to the end of distribution. It is necessary to perform Internet communication with the terminal while a session is established between the port 126 of the server and the port 152 of the user terminal.
When a distribution request is sent from the user terminal, the video server 120 reads the corresponding video file from the media storage 110 and transmits it to the user terminal. The read buffer 122 is a buffer used when reading a video file stored in the media storage 110 to the video server 120. The transmission buffer 124 is a buffer used for transmitting a video file from the video server 120 to the Internet 140.

On the other hand, when the user terminal selects a program that the user wants to watch, a video file corresponding to the program is distributed from the server, played by the video player 156, and can be viewed by the user. As the video player 156 on the user terminal side, for example, a currently used one such as Windows (registered trademark) Media Player is used.
The user can select a program by, for example, accessing the home page of the server from the user terminal, and selecting a hyperlink or button corresponding to the desired program from the Web page of the program list displayed on the browser of the user terminal. A method of selecting by an operation such as clicking can be employed.

Here, in order to insert and distribute the advertisement video into the video of the program selected by the user using the movie list method (hereinafter referred to as “main video”), for example, a video list corresponding to each program in advance on the server side. It is possible to prepare a method. The video list is a list in which the main video file of the program and the names of advertisement video files to be inserted are described in the order of distribution (playback order).
FIG. 3 is an example of a video list prepared for a certain program. Before and after each video file of the main video VOD-1, VOD-2, VOD-3 corresponding to the selected program (for example, the video file names of the main videos obtained by dividing one program into three) In the figure, it is shown that the video files of the advertisement videos CM-1, CM-2, CM-3 and CM-4 are continuously played back.
Note that the advertisement video may have a specific advertisement video file name (CM-1 to CM-4 in the example of FIG. 3) described in the video list in advance, or the server may request a distribution request from the user terminal. An advertisement video may be arbitrarily selected.

The distribution request from the user terminal to the server is performed by executing, for example, OCX (OLE Custom Control). OCX is synonymous with OLE control, and is a software component created in compliance with OLE (Object Linking and Embedding), which is a mechanism for realizing data linkage between application software in Windows (registered trademark). Instead of OCX, a script language such as Java (registered trademark) Script that can be executed on the user terminal may be used.
As shown in the block diagram of FIG. 2, the OCX 154 is prepared in advance by transmitting it from a server or the like to the user terminal. When the user selects a program that the user wants to watch by an operation such as clicking as described above, a video list corresponding to the program is sent from the server to the user terminal. The OCX 154 activates the video player 156 of the user terminal, sends a distribution request for the main video and the advertisement video to the server according to the video list, and plays the distributed video file on the video player 156.

At this time, in the conventional movie list method, a series of exchanges shown in the communication sequence of FIG. 4 is performed between the server, the OCX 154, and the video player 156 in order to perform distribution from the server and reproduction on the user terminal according to the video list. is required. This series of exchanges is performed via the user terminal port 152 and the server port 126.
The OCX 154 first activates the video player 156 and requests the server to distribute the first video file (CM-1 in FIG. 3) in the video list (S411). In response to the distribution request, the server reads the advertisement video file (CM-1) from the media storage 110 and distributes it to the user terminal (S412). The distributed video file (CM-1) is stored in a buffer in the video player 156 and reproduced (S413). When the reproduction is completed, a reproduction completion signal is transmitted from the video player 156 to the OCX 154 (S414). In response to the end of playback, the OCX 154 requests the server to distribute the next video file (VOD-1 in FIG. 3) in the video list (S421).
Similarly, the above distribution request (S431, S441,...), Distribution (S422, S432,...), Reproduction (S423, S433,...) In order up to the last video file in the video list (CM-4 in FIG. 3). ), The reproduction end (S424, S434,...) Is repeated.

In the video player 156 such as Windows (registered trademark) Media Player which is generally used in a user terminal such as a personal computer, an exchange such as the communication sequence of FIG. This is because reproduction processing (reception to the buffer and reproduction by the video player) cannot be performed. In addition, since only the playback end signal can be passed from the video player 156 to the OCX 154, when a plurality of video files are sequentially delivered to the user terminal and are continuously played back by one video player 156, the server and the user terminal It is necessary to perform a series of exchanges between the server and the port 126 of the server and the port 152 of the user terminal while keeping a session.
As a result, in the conventional movie list method, it is necessary to make a distribution request for the next video file to the server after each video file in the video list has been played, and after the previous video file has been reproduced. Due to the delay from the end of playback of one video file to the start of playback of the next video file, the video on the video player 156 is interrupted, resulting in a blank time. In particular, when a plurality of advertisement videos are played back, there is a problem that a large number of blank times occur and the user's satisfaction cannot be obtained.

  An object of the present invention is to solve the above-mentioned problem, that is, the problem that a blank time is generated between video files in the movie list method, by the configuration on the server side.

In order to solve the above problems, the present invention provides a video distribution system for distributing video to a user terminal, wherein the video storage means stores a video file, and the video file is read from the video storage means. Video transmission means for transmitting to the user terminal, wherein the video transmission means switches at least two buffer storage means and a video file read from the video storage means to the plurality of buffer storage means for each file. And a buffer control means for sequentially switching and reading from the plurality of buffer storage means for each file, and when there are a plurality of video files corresponding to the program, the video distribution is performed without a blank time between the files. System.
A plurality of video files transmitted in this way can be reproduced as one file with no blank time at the user terminal.
The present invention is also a video distribution system for distributing video to a user terminal, wherein the video storage means stores a video file, and a program selection page is transmitted to the user terminal when accessed from the user terminal. Program page transmitting means, program receiving means for receiving the program selected on the program selection page, and video transmitting means for reading a video file corresponding to the program from the video storage means and transmitting it to the user terminal. And the video transmission means writes at least two buffer storage means and a video file read from the video storage means to the plurality of buffer storage means for each file, and writes the video file from the plurality of buffer storage means for each file. And a buffer control means for sequentially switching to and reading out video files corresponding to programs. If yl there are multiple, a video distribution system and transmits without time gaps between files.
With this configuration, a video file of a program can be distributed on demand in response to a program distribution request from the user terminal.
The video storage means also stores an advertisement video file, and further includes user information storage means for storing user information including information such as the user's age, sex, and preferences, and distribution information corresponding to the advertisement video file. Distribution information storage means for storing, wherein the video transmission means reads user information corresponding to the user terminal from the user information storage means and uses the distribution information in the distribution information storage means to conform to the user information. The advertisement video file to be read may be read from the video storage means, inserted into the program, and transmitted to the user terminal.
By having the distribution information corresponding to the advertisement video file, it is possible to insert and distribute the advertisement video suitable for the user's age, sex, preference, etc. for each user.
The video transmission means measures the time from the read instruction to the video storage means to the start of writing to the buffer storage means, and uses this as a delay time, and the capacity of the buffer storage means. Capacity changing means for changing according to the delay time may be further included, and the capacity of the buffer storage means may be determined based on the delay time.
When distributing a program to a user terminal, the delay time is measured by the delay measuring means, and a buffer capacity necessary for video distribution to the user terminal can be prepared according to the delay time. Thereby, the memory of the server can be used without waste.
Further, the video transmission means may use the delay time from the delay measurement means to issue a read instruction to the video storage means without waiting for the previous video file read end.

A server program for causing a computer to function as video transmission means for reading a video file from a video storage means and transmitting it to the user terminal, wherein the video transmission means includes at least two buffer storage means and the video storage means. A video corresponding to a program has a function as a buffer control means for switching and writing a video file read from each of the plurality of buffer storage means for each file, and sequentially switching and reading each file from the plurality of buffer storage means. When there are a plurality of files, the server program is also characterized in that transmission is performed without a blank time between files.
A program page transmitting means for transmitting a program selection page to the user terminal when accessed from the user terminal; a program receiving means for receiving a program selected on the program selection page; and a video file corresponding to the program. A server program that causes a computer to function as a video transmission unit that is read from a video storage unit and transmitted to the user terminal, wherein the video transmission unit includes at least two buffer storage units and a video file read from the video storage unit Is written to the plurality of buffer storage means for each file, and buffer control means for sequentially switching and reading each file from the plurality of buffer storage means. When there are a plurality of video files corresponding to the program, A server characterized by transmitting without a blank time between Program is also the present invention.
The video storage means also stores an advertisement video file, and the video transmission means reads user information including information such as the user's age, sex, and preferences from the user information storage means and reads from the distribution information storage means The advertisement video file that matches the user information is read from the video storage means using the distribution information corresponding to the advertisement video file, inserted into the program, and transmitted to the user terminal. .
The video transmission means measures the time from the read instruction to the video storage means to the start of writing to the buffer storage means, and uses this as a delay time, and the capacity of the buffer storage means. It further has a function as capacity changing means for changing according to the delay time, and the capacity of the buffer storage means may be determined by the delay time.
Further, the video transmission means may use the delay time from the delay measurement means to issue a read instruction to the video storage means without waiting for the previous video file read end.

According to the video distribution system of the present invention, information relating to user characteristics is registered at the time of user registration, and an advertisement video file suitable for each user is distributed. Therefore, a more effective advertisement can be performed.
Further, according to the new movie list method used in the video distribution system of the present invention, a plurality of video files in the video list can be played back by the video player of the user terminal without causing a blank time. Since the playback video is not interrupted, user satisfaction can be increased.

  Hereinafter, embodiments of the video distribution system of the present invention will be described in detail with reference to the drawings.

<Video Distribution System of this Embodiment>
FIG. 5 is a diagram showing a system configuration example of the video distribution system according to the present embodiment.
The video distribution system according to this embodiment includes a server 570 and a user terminal 550, which communicate with each other via the Internet 540.
The user terminal 550 is a terminal that can be connected to the Internet, such as a personal computer, a mobile phone, or a PDA. The server 570 is a server that performs registration processing of a user (a person who receives video distribution using the user terminal 550) and distributes video in response to a request from the user terminal 550.

(server)
In the server 570, the media storage 560 is a storage device for storing video files of all produced main videos (program videos) and advertisement videos.
The IP videophone 572 is a system that provides an IP videophone service to the user terminal 550. In addition, for example, a system that provides a blog service (particularly, a video blog service including video) may be provided in the server 570.
The video server 580 is a server that reads a necessary video file from the media storage 560 in order to distribute video to the user terminal 550. Here, the video server is not necessarily a physically independent server but a server program that reads a video file from the media storage 560. In this embodiment, the main video server 582 for reading out the main video file and the advertisement video server 584 for reading out the advertisement video file are prepared in the server 570, but the number and arrangement of the video servers are not limited thereto.

The video inserter 590 is a program for performing processing for causing the video player of the user terminal 550 to play back video files listed in the video list in a new movie list method (method 1) proposed later. It is.
The ID information database 574 is a database that stores user information. The main items constituting the ID information database 574 are shown in FIG.
The distribution record database 576 is a database that stores distribution histories to each user terminal 550 (distributed main video file name and advertisement video file name, distribution date and time, etc.).
The video inserter 590 will be described in detail later. Each item (user information) in the ID information database 574 will be described in detail in a later section (User Registration Process).

(User registration process)
In this embodiment, video distribution from the server 570 to the user terminal 550 is performed.
When the user first receives a distribution service by the video distribution system of the present embodiment, the user accesses the server 570 and inputs user information including regional information. The input user information is stored in each item of “user information” in the ID information database 574 shown in FIG.

Here, each item of “user information” in FIG. 6 will be described.
“User ID” is an ID for identifying a user, and is automatically given by the system at the time of user registration, for example.
“Region”, “Preference”, “Age”, and “Gender” are information input by the user at the time of user registration. The “region” is a region where the user lives (uses the user terminal 550), and for example, a prefecture is selected. “Age” and “gender” are the age and sex of the user. “Preferences” are set by the user selecting an appropriate item (for example, favorite color, hobby, etc.) that is predetermined for the user's preference.
These “region”, “preference”, “age”, and “gender” are used when distributing an advertising video that matches the characteristics of the user. Therefore, more items can be provided in order to judge characteristics more precisely.

FIG. 7 is a diagram showing a communication sequence between the user terminal 550 and the server 570 during the user registration process.
First, when a user accesses a homepage prepared in advance in the server 570 from the user terminal 550 (S710), a user registration page is displayed on the browser of the user terminal 550 (S720). The user registration page is a Web page displaying an input field for the user to input his / her information.
The user inputs the above-mentioned database items such as region, taste, age, and gender. The input content is transmitted to the server 570 (S730) and stored in the ID information database 574 of the server 570 (S740). Further, a user ID is given by the server 570 and stored in the ID information database 574.
Next, the OCX used in the subsequent video distribution processing is transmitted from the server 570 to the user terminal 550 (S750). The OCX is prepared in advance in the server 570, and the server 570 describes the user ID and area of the user and transmits the user ID to the user terminal 550. The function of OCX will be described in detail later. As described above, a script language such as Java (registered trademark) Script that can be executed on the user terminal 550 may be used instead of the OCX.
As a result, the user terminal 550 can receive subsequent video distribution from the server 570.

(Video distribution processing)
Next, processing when video distribution to the user terminal 550 is performed will be described.
FIG. 8 is a diagram showing a communication sequence between the user terminal 550 and the server 570 during the video distribution process.
First, the user terminal 550 accesses the home page of the server 570 (S810). At this time, the user registration page described in the above-described user registration process is displayed on the user terminal 550, and the server 570 transmits an activation command to activate the OCX of the user terminal 550 to the user terminal 550 (S820).
The OCX accesses the menu page of the server 570 according to the URL given to the OCX (S830) and sends an ID necessary for user authentication. Therefore, when the user authentication is performed at the server 570 (S835), the displayed user registration is displayed. The page automatically changes to the menu page (S840).

That is, since the OCX is given from the server 570 to the user terminal 550 at the time of user registration, in the case of an already registered user, it is possible to proceed to the process of starting OCX and performing video distribution as described above. On the other hand, since OCX does not start for a user who is not registered, it is possible to maintain a state where the user can register while displaying the user registration page on the browser. When the user performs a registration operation, the user registration process shown in FIG. 7 is performed.
In the present embodiment, as described above, the OCX is automatically activated by the activation command from the server 570 and the user authentication is performed by transmitting the ID or the like to the server 570. However, the authentication may be performed by other methods. For example, there is a method in which a user manually inputs a user ID (and a password or the like) at the user terminal 550 and the server 570 inquires and authenticates user information in the ID information database 574.

  An example of the menu page (S840) displayed on the user terminal 550 as described above is shown in FIG. The menu page 900 is a Web page on which a button for selecting a service provided by the video distribution system of the present embodiment is displayed. When the user clicks the “IP videophone” button 910, the user terminal 550 can use the IP phone service by the IP videophone system (572 in FIG. 5). When the “video distribution” button 920 is clicked, the user terminal 550 can use the video distribution service by the video distribution system of this embodiment.

Here, it is assumed that the user has selected the “video distribution” service. When the menu is selected (S850), a video distribution page is transmitted from the server 570 (S860).
An example of the video distribution page is shown in FIG. The video distribution page 1000 displays a list of program names 1010 (program 1, program 2, program 3,...).
Further, on the right side of each program name 1010, a “select” button 1020 for the user to select the program is displayed. In addition to displaying the “select” button 1020, a method such as displaying a program name as a hyperlink may be used. In addition to the program name, information such as the name of the performer and the time of the program may be displayed. Further, the pages and display columns may be displayed separately according to the genre of the program so that the user can easily see them.
In response to the click of the “select” button 1020 for each program, a video list as shown in FIG. 11 is sent from the user terminal 550 to the server 570. FIG. 11 shows an example of a video list corresponding to program 1 (VOD-1). A total of four video lists before and after the three main video files VOD-1-1, VOD-1-2, and VOD-1-3. It shows that an advertisement video file (CM) is distributed. Here, the video list is sent from the user terminal 550 to the server 570, but for example, only the program selection is sent from the user terminal 550, and the server 570 side prepares in advance based on the selected program. The video list may be referred to.

When the user selects a program that the user wants to watch (S870), the server 570 generates an advertisement distribution schedule for the user (S880). The advertisement distribution schedule is obtained by selecting an advertisement video file that matches the user information of the user from the advertisement video files stored in the media storage 560.
FIG. 12 shows an example in which the advertisement distribution schedule is shown in a list. For the advertising video files CM-1 to CM-m stored in the media storage 560, the title of the advertising video (which may be a file name or the like) and the distribution frequency are displayed.
The distribution frequency is a frequency of distributing the advertisement file (weighting in all advertisement video files). In a simple example, when CM-1 has a distribution frequency 1 and CM-2 has a distribution frequency 2, CM-1 is for the first user, CM-2 for the next user, and the next user. , Such as CM-2, the total number of distributions (here, 3 times) corresponds to this distribution frequency (of 3 times, CM-1 is 1 time and CM-2 is 2 times). . The distribution frequency is determined according to, for example, a fee paid by the advertiser.
In each advertisement video file, in addition to the distribution frequency, the contents of items corresponding to user information (here, region, gender, age, preference) are registered in advance. For example, if you want to target the distribution of “male who are interested in travel in their 20s and 30s living in the Kanto area” for the advertisement video of a car, the advertisement video file is “Region”, “Gender”, “Age”, “Preference”. This can be determined for each item. Of course, these items may be set as necessary, and some or all of the items may be “unquestioned”.

The circles and diagonal lines shown in the advertisement distribution schedule in FIG. 12 indicate that a certain user matches the distribution condition of the advertisement video. In FIG. 12, CM-2 matches the region, CM-3 matches the gender and age, CM-4 matches the preference, and CM-m matches the gender. Therefore, CM-2, CM-3, CM-4, and CM-m are distributed to the user in order or arbitrarily in consideration of the distribution frequency determined for each advertisement video.
FIG. 13 is an example in which an advertisement video is selected according to the advertisement distribution schedule of FIG. 12 and the video list of FIG. 11 is completed. FIG. 13 shows that CM-2, CM-3, CM-4, and CM-4 are listed.
Next, the server 570 records the distribution history in the distribution record database 576 according to the completed video list (FIG. 13) (S885). Then, the main video file and the advertisement video file are distributed to the user terminal 550 (S890). The distribution of the video file to the user terminal 550 will be described in detail later.
The distribution history recorded in the distribution record database 576 can be used, for example, for a service such as allowing a user to view a program that has been distributed so far on a Web page. It is also possible to refer to this distribution history at the time of video distribution, for example, to preferentially distribute an advertisement video that has not been distributed to the user (or has not been distributed recently).

  As described above, according to the video distribution system of the present embodiment, information related to user characteristics is registered in the server 570 at the time of user registration, so that an advertisement video file suitable for each user can be distributed, which is more effective. Advertising can be done.

<Movie list method proposed in this embodiment>
As described in the section of the prior art, when trying to play video files continuously on a single video player using the conventional movie list method, the video files in the video list are played one by one and the previous video file is played. It is necessary to make a distribution request to the server after the process ends. Therefore, the conventional movie list method has a problem in that the video on the video player is interrupted between the end of playback of one video file and the start of playback of the next video file, resulting in a blank time.
In the present embodiment, each video file in the video list is formed as one video file without causing a blank time by using a video player that is generally used at present (for example, Windows (registered trademark) Media Player). We propose a new movie list method that can be played. In this method, the server 570 performs control (delay control) to eliminate the blank time.
Hereinafter, this method will be described in detail.

(Movie list method proposed in this embodiment)
The movie list method proposed in the present embodiment does not request distribution of video files in the video list one by one from the user terminal 550 as in the conventional movie list method, but uses the video list in the server 570, In this system, the delay between video files is controlled so that these video files can be distributed without blank time, and the user terminal 550 is continuously distributed so that one file is reproduced.
That is, in this system, a plurality of (here, two) buffers are prepared in the server 570 in response to one program distribution request, and video files in the video list are sequentially (2 In this case, the video files of the program are transmitted to the user terminal 550 without a blank time by accumulating and sequentially switching (reading) each video file. Here, in this method, in order to save the capacity of the buffer prepared above, the delay in the server 570 is measured, and the buffer capacity is determined according to the delay time. Further, the buffer capacity can be further saved by issuing the delivery request for each video file early in consideration of this delay time.
In this method, since this delay control is performed by the video inserter 590 of the server 570, it is not necessary to newly prepare a special device or software for the user terminal 550.
FIG. 14 is a block diagram showing video distribution processing according to this method. Hereinafter, the processing of this method will be described in detail with reference to this block diagram.

(Processing on the user terminal side)
When the user selects a program to be viewed on the video distribution page, the OCX 554 of the user terminal 550 activates the video player 556 as shown in FIG.
Since these video files are distributed from the server 570 without any blank time, the video player 556 can reproduce them as one video file. When the reproduction is completed, a reproduction completion signal is passed to the OCX 554.

(Server-side processing)
On the other hand, the server 570 performs the processing shown in the block diagram of the video inserter 590 in FIG. 14 and the flowchart in FIG. 15, accumulates video files in the transmission buffer 595 without blank time in the order of the video list, and distributes them to the user terminal 550. To do. Hereinafter, processing performed by the server 570 will be described with reference to these drawings.
First, as pre-processing, when the user terminal 550 activates the video player 556 and a session is established between the port 552 and the port 578 of the server 570 in order to receive a video file, the video inserter 590 has one user (session) ) Two virtual video players (virtual video player 1 591 and virtual video player 2 593) are generated. Note that although two virtual video players are described here, three or more virtual video players can be generated and used in this method. These virtual video players are not actually displayed on the display device, but behave in the same manner as the video player 556 of the user terminal 550.

Next, the video inserter 590 measures the delay of the server 570 (S1510). This delay time is the time from when the video inserter 590 instructs the virtual video player to issue a distribution request to the video server 580 until playback starts on the virtual video player. Since this time varies depending on factors such as the number of user terminals currently accessing the server 570, the time is measured each time there is an access from the user terminal 550 (a session is established between the port 552 and the port 578). The delay is measured, for example, by playing a test video file prepared in advance in the media storage 560 of the server 570 using the virtual video player activated above.
In this method, in order to accurately grasp the delay time, the main video file and the advertisement video file are physically stored in the same place (here, the media storage 560 of the server 570), and the main video server 582 It is desirable to place the advertising video server 584 on the same physical server as the video inserter 590 (here, server 570). This is because, through other networks and the Internet, various factors overlap the transmission path delay, and it is difficult to control this.

Next, a memory for a transmission buffer (transmission buffer 1 592, transmission buffer 2 594) used corresponding to each virtual video player (virtual video player 1 591, virtual video player 2 593) according to the measured delay time. Is secured (S1520). These transmission buffers are buffers in which the video server 580 reads and alternately stores the video files so that the video files can be sequentially stored without spaces in the transmission buffer 595 for transmitting the video files to the user terminal 550.
As described above, if the memory for the transmission buffer is secured in accordance with the delay time, the resources of the server 570 can be used without waste. Therefore, this method can be applied even when a small server is used as the server 570. . For example, when the server 570 has sufficient resources, it is possible to secure a sufficient memory for processing without measuring the delay time (S1520).
Next, the video inserter 590 receives the video list (see FIG. 11) from the user terminal 550 (S1530), generates the advertisement video distribution schedule (see FIG. 12) as described above (S1540), and distributes it. The advertisement video file to be determined is determined, and the video list is completed (see FIG. 13) (S1550). As described above, instead of receiving the video list from the user terminal 550, for example, only the program selection is sent from the user terminal 550, and the video list prepared in advance corresponding to the program on the server 570 side is sent. You may make it refer.

Thereafter, the video inserter 590 reads out the completed video list one by one, and alternately executes a plurality (here, two) of virtual video players (virtual video player 1 591 and virtual video player 2 593) (S1560).
That is, as indicated by an arrow in FIG. 14, the virtual video player is instructed to issue a video file distribution request to the video server 580. Then, the virtual video player makes a distribution request to the video server 580, and the video server 580 reads the video file from the media storage 560 in response to the distribution request, and transmits a transmission buffer (transmission buffer 1592 or transmission) corresponding to the virtual video player. Buffer 2 594). In this manner, video files are alternately stored in the transmission buffer 1 592 and the transmission buffer 2 594.
Each time the playback of the video file is finished in the virtual video player, the video inserter 590 that has received the playback end signal issues a playback start command to the other virtual video player and sends it to the corresponding transmission buffer 1592. The buffer 2 594 is switched to switch the output to the transmission buffer 595. In this manner, a plurality of video files can be written to the transmission buffer 595 without a blank time.
Thereafter, the video inserter 590 repeats the above process alternately for the two virtual video players until the video file is completed (until S1570 in FIG. 15 becomes Yes). When the distribution of all the video files in the video list is completed, the session between the port 552 and the port 578 of the server 570 is terminated.

  In this manner, the video inserter 590 performs delay control in this manner, whereby the video files in the video list can be sequentially stored in the transmission buffer 595 without causing a blank time. As a result, the video player 556 of the user terminal 550 only needs to reproduce the video data sent from the transmission buffer 595 as one video file. Then, when the OCX 554 receives a reproduction end signal from the video player 556, a series of program distribution processing ends.

In addition, as described above, the next video in the video list is a little earlier than the end of reproduction (end of reading of the video file to the transmission buffer 595) in one virtual video player in consideration of the measured delay time (S1510). If a file distribution request is issued to the other virtual video player, it is possible to further save the buffer capacity of the transmission buffers 1 and 2 ensured (S1520).
This process will be described for each of T0 to T6 in the time chart of FIG. 16A with reference to the block diagram of FIG. Note that the video file names displayed in FIGS. 16A and 16B correspond to the video list shown in FIG.
(T0) The video inserter 590 instructs the virtual video player 1 591 to make a distribution request for the first video file CM-2 in the video list to the video server 580.
Then, as described above, the virtual video player 1 591 transmits a CM-2 distribution request to the video server 580, and the video server 580 reads the advertisement video file CM-2 from the media storage 560 using the read buffer 586. And stored in the transmission buffer 1 592. Then, the virtual video player 1 591 operates as if CM-2 is being played, starts playing, and the video inserter 590 starts writing CM-2 from the transmission buffer 1 592 to the transmission buffer 595. Here, the time from the distribution request instruction (T0) to the start of CM-2 playback (writing to the CM-2 transmission buffer 595) by the virtual video player 1591 is the CM- in FIG. 2 is a hatched portion on the left side.

(T1) Next, the video inserter 590 instructs the virtual video player 2 593 to request the video server 580 to distribute the second video file (VOD-1-1) in the video list. Here, this instruction indicates that the server of the server measured as described above is such that playback of VOD-1-1 on the virtual video player 2 593 can be started as soon as CM-2 playback on the virtual video player 1 591 ends. In consideration of the delay time, it is performed earlier than the end of the reproduction of CM-2.
In response to this instruction, the virtual video player 2 593 sends a VOD-1-1 distribution request to the video server 580. The video server 580 reads the main video file VOD-1-1 from the media storage 560 using the read buffer 586, and starts accumulation in the transmission buffer 2594.

(T2) When the virtual video player 1 591 sends a signal indicating that the reproduction of CM-2 is finished, the video inserter 590 instructs the virtual video player 2 593 to start playing the VOD-1-1 and sends the transmission buffer 595. The buffer for outputting the video file is switched from the transmission buffer 1 592 to the transmission buffer 2 594. As a result of issuing the instruction earlier by the hatched lines T1 to T2, the video file reproduction and the writing to the transmission buffer 595 can be performed alternately and without interruption. Here, since the capacity of the transmission buffer only needs to be accumulated for T1 to T2, the buffer capacity can be saved as compared with the above-described method. VOD-1-1 is stored in the transmission buffer 595 following the previous CM-2 and transmitted to the user terminal 550.

Thereafter, until the video file ends (until S1570 in FIG. 15 becomes Yes), the video inserter 590 alternately repeats the same processing as described above for the two virtual video players.
Specifically, as shown in FIG.
(T3) Instruct CM-3 distribution request to virtual video player 1 591 (T4) Instruct to switch output from transmission buffer 2 594 to transmission buffer 1 592 (T5) VOD-1− to virtual video player 2 593 2 distribution request (T6) The processing of the output switching instruction from the transmission buffer 1 592 to the transmission buffer 2 594 is sequentially performed for all the video files listed in the video list.

  By the processing of the video inserter 590 described above, in this method, as shown in FIG. 16B, the video files in the video list can be sequentially sent to the transmission buffer 595 without causing a blank time, and the transmission buffer 1 The capacity of the memory used for 592 and the transmission buffer 2 594 can be further saved.

It is a system configuration example of a conventional video distribution system. It is a block diagram in the case of using the conventional movie list system in the conventional video delivery system. It is an example of the video list prepared corresponding to a program by the conventional movie list system. This is a communication sequence in the case of performing distribution / playback processing using a video list in the conventional movie list method. It is an example of a system configuration | structure of the video delivery system of this embodiment. It is a figure which shows the example of the item which comprises the ID information database of this embodiment. It is a communication sequence between the user terminal and the server at the time of user registration in this embodiment. It is a communication sequence between the user terminal and the server at the time of video delivery in this embodiment. It is an example of the menu page of this embodiment. It is an example of the video delivery page of this embodiment. It is an example of the video list prepared corresponding to a program in this embodiment. It is an example of the advertisement video delivery schedule produced | generated in this embodiment. 13 is a video list of FIG. 11 completed according to the advertisement video distribution schedule of FIG. 12 in the present embodiment. It is a block diagram of the new movie list system proposed in this embodiment. It is the flowchart which showed the process of the video inserter of this system. It is the figure which showed the control by the video inserter of this system in time series.

Claims (10)

A video distribution system for distributing video to user terminals,
Video storage means for storing video files;
Video transmission means for reading a video file from the video storage means and transmitting it to the user terminal;
The video transmission means includes
At least two buffer storage means;
A buffer control means for switching the video file read from the video storage means for each file to the plurality of buffer storage means for writing, and sequentially switching for each file from the plurality of buffer storage means;
A video distribution system, wherein when there are a plurality of video files corresponding to a program, transmission is performed without a blank time between the files. A video distribution system for distributing video to user terminals,
Video storage means for storing video files;
A program page transmission means for transmitting a program selection page to the user terminal when accessed from the user terminal;
Program receiving means for receiving the program selected on the program selection page;
Video transmission means for reading a video file corresponding to the program from the video storage means and transmitting it to the user terminal;
The video transmission means includes
At least two buffer storage means;
A buffer control means for switching the video file read from the video storage means for each file to the plurality of buffer storage means for writing, and sequentially switching for each file from the plurality of buffer storage means;
A video distribution system, wherein when there are a plurality of video files corresponding to a program, transmission is performed without a blank time between the files. The video distribution system according to claim 2.
The video storage means also stores an advertisement video file,
Furthermore, user information storage means for storing user information including information such as the user's age, sex, and preferences,
Distribution information storage means for storing distribution information corresponding to the advertisement video file,
The video transmission means reads user information corresponding to the user terminal from the user information storage means, and uses the distribution information of the distribution information storage means to use the video storage means for the advertising video file that matches the user information. The video distribution system is characterized in that the video distribution system is read out from the program, inserted into the program, and transmitted to the user terminal. In the video delivery system in any one of Claims 1-3,
The video transmission means includes
A delay measuring means for measuring a time from a reading instruction to the video storing means to starting writing to the buffer storing means and setting this as a delay time;
Capacity changing means for changing the capacity of the buffer storage means according to the delay time;
A video distribution system characterized in that a capacity of the buffer storage means is determined by the delay time. The video distribution system according to claim 4.
The video transmission system uses the delay time from the delay measurement unit to generate a read instruction to the video storage unit without waiting for completion of previous video file reading. A server program that causes a computer to function as a video transmission unit that reads a video file from a video storage unit and transmits the video file to the user terminal,
The video transmission means includes
At least two buffer storage means;
The video file read from the video storage means is switched and written to the plurality of buffer storage means for each file, and has a function as a buffer control means for sequentially switching and reading from the plurality of buffer storage means for each file,
A server program characterized in that when there are a plurality of video files corresponding to a program, transmission is performed without a blank time between the files. A program page transmitting means for transmitting a program selection page to the user terminal when accessed from the user terminal;
Program receiving means for receiving the program selected on the program selection page;
A server program that causes a computer to function as a video transmission unit that reads a video file corresponding to the program from a video storage unit and transmits the video file to the user terminal,
The video transmission means includes
At least two buffer storage means;
A buffer control means for switching the video file read from the video storage means for each file to the plurality of buffer storage means for writing, and sequentially switching for each file from the plurality of buffer storage means;
A server program characterized in that when there are a plurality of video files corresponding to a program, transmission is performed without a blank time between the files. The server program according to claim 7,
The video storage means also stores an advertisement video file,
The video transmission means reads user information including information such as the user's age, sex, and preferences from the user information storage means, and uses the distribution information corresponding to the advertisement video file read from the distribution information storage means, A server program characterized in that the advertisement video file suitable for information is read from the video storage means, inserted into the program, and transmitted to the user terminal. In the server program in any one of Claims 6-8,
The video transmission means includes
A delay measuring means for measuring a time from a reading instruction to the video storing means to starting writing to the buffer storing means and setting this as a delay time;
A function of capacity changing means for changing the capacity of the buffer storage means according to the delay time;
A server program, wherein the capacity of the buffer storage means is determined by the delay time. The server program according to claim 9,
The server program characterized in that the video transmission means uses the delay time from the delay measurement means to issue a read instruction to the video storage means without waiting for completion of the previous video file reading.

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