JP2004282730A - Video data distribution system and video data distribution method - Google Patents

Abstract

【Task】
Provided is a technique for storing video and audio in a location that cannot be captured by a surveillance camera in a video storage / delivery device so that the video and audio can be distributed.
[Solution]
A mobile terminal with an imaging function and a video storage / delivery device are connected via the Internet or the like, and video data captured by the mobile terminal is stored in the storage / delivery device, and can be distributed to a browser PC or a mobile terminal. A data conversion device for converting a protocol and a data format is provided between the mobile terminal and the video accumulation / delivery device, and an authentication server for permitting communication with a specific mobile terminal is provided. With this configuration, audio data can be transmitted and received between the mobile terminal, the mobile terminal with an imaging function, and the browser PC.
[Selection diagram] Fig. 1

Description

  The present invention relates to a technique for storing and delivering video data transmitted from a mobile terminal.

  In recent years, in a system for monitoring an intruder using a surveillance camera, a technology of video distribution using a network such as the Internet or a LAN, a technology of storing video as digital data in a storage device such as a hard disk or a DVD, Techniques have been developed for viewing images distributed by distribution technology on mobile terminals. These techniques are described in, for example, JP-A-2002-24330 (Patent Document 1) and JP-A-2003-6277 (Patent Document 2).

JP-A-2002-24330

JP-A-2003-6277

In the above-described conventional technology, the monitoring camera 1001 is a camera whose installation position is fixed, and therefore can only capture an image of a specific location. For this reason, it is impossible to acquire an image at a place where the monitoring camera 1001 is in a blind spot or at a place where the monitoring camera 1001 is not installed. This camera may be equipped with a swivel table, but in that case, a blind spot due to an obstacle or the like becomes a problem.
An object of the present invention is to provide a video storage and distribution device capable of storing and distributing video data and audio data of a place where imaging and recording cannot be performed by a surveillance camera in view of the situation of the related art described above. It is an object of the present invention to realize a video conference system using a PC (Personal Computer).
An object of the present invention is to provide a technique capable of solving such a problem.

  In order to solve the above problems, the present invention basically uses a portable terminal with an imaging function (with an imaging device) to accumulate video data of a shot video in a video accumulation and distribution device and make the video data available for distribution. In addition, the format of the video data generated by the mobile terminal with an imaging function is converted into a format of video data that can be stored in the video storage and delivery device. Further, audio data can be handled between the portable terminal and the browser PC. Further, by providing an authentication server, data transmitted from a specific terminal can be stored, and data can be distributed to another specific terminal.

In particular,
(1) As a video data distribution system for distributing video data via a network, a video storage / distribution device for storing and distributing video data, and a format of video data generated by a mobile terminal with an imaging function, And a data conversion device for converting the stored video data into a format that can be received by the portable terminal with an imaging function and permitting data from a specific terminal. An authentication server for authenticating the transmitting mobile terminal for storing the video data transmitted from the mobile terminal with an imaging function as the transmitting mobile terminal, the stored video data, from the terminal side including other mobile terminals In response to the transmission request of the terminal.

  (2) As a data conversion device for a video distribution system that stores and distributes video data in a video storage and distribution device, the video storage and distribution device can store the format of video data generated by a mobile terminal with an imaging function. Data that can be converted to the format of video data and that authenticates the receiving mobile terminal to deliver the data to a specific terminal, and that the stored video data can be received by the mobile terminal with the imaging function that is the receiving mobile terminal. A configuration for protocol conversion is provided.

  (3) As a video data distribution method for distributing video data via a network, a step of authenticating a portable terminal transmitting data, a step of receiving video data from the portable terminal via a network, and a step of receiving the received video data Converting the format into a storable video data format, storing the converted video data, and receiving a transmission request signal for storage data from a terminal including other mobile terminals, Authenticating the mobile terminal that receives the data, and converting the stored data requested to be transmitted from the terminal to video data that can be received by the terminal, and converting the converted video data. Transmitting the video data transmitted from the mobile terminal through the step of transmitting the video data to the terminal via the network, and storing the stored video data. The data is distributed to the terminal side according to the transmission request from the terminal side.

  According to the present invention, it is possible to store and distribute a wide range of video data together with audio data. It is also possible to configure a video conference system or the like.

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.
FIG. 22 is a block diagram showing a configuration of a network monitoring system centered on a storage and delivery device. 1001 is a surveillance camera, 1002 is a LAN (Local Area Network) transmission path, 1003 is a Web encoder, 1004 is a hub, 1005 is a video storage / delivery device, 1005 is a browser PC, 1006 is a video browsing data conversion device, and 1008 is public. A transmission line by a line, 1009 may be a WAN (Wide Area Network) such as the Internet, 1010 may be a wireless transmission line, and 1011 may be a mobile terminal for viewing images (or at least an information terminal device including a mobile terminal with an imaging function). ). The monitoring camera 1001, Web encoder 1003, video storage / delivery device 1005, browser PC 1006, and video browsing data conversion device 1007 are connected by a hub 1004, and the above devices are connected by a LAN transmission path 1002. The video browsing data conversion device 1007 and the portable terminal 1011 are connected by a transmission line 1008 of a public line, a WAN 1009 and a transmission line 1010 by wireless.

  FIG. 23 is a diagram schematically illustrating an example of a hardware configuration of the video storage / delivery device 1005, the browser PC 1006, the video browsing data conversion device 1007, and the mobile terminal 1011. 1101 is a CPU (Central Processing Unit), 1102 is a memory, 1103 is a network interface, 1104 is a storage device, 1105 is a sound input / output interface, 1106 is a speaker, 1107 is a microphone, 1108 is a video interface, 1109 is a monitor, and 1110 is an input. An interface 1111 is an input device such as a keyboard, 1112 is a pointing device such as a mouse, and 1113 is a bus. 1101 to 1105, 1108 and 1110 are mutually connected via a bus 1113, and a speaker 1106 and a microphone 1107 are connected to a sound interface 1105. The monitor 1109 is connected to the video interface 1108. Further, the input device 1111 and the pointing device 1112 are connected to the input interface 1110. Although not shown, the network interface 1103 is connected to a LAN transmission line 1002, a public line 1008, and a wireless transmission line 1010 as necessary. Note that the configuration shown in FIG. 23 may be different depending on system requirements.

  Hereinafter, a method of storing the video captured by the monitoring camera 1001 in the storage and delivery device 1005 in the system illustrated in FIG. 22 will be described. The monitoring camera 1001 is a fixed camera installed at a certain point. A video signal representing a video captured by the camera is transmitted to the Web encoder 1003. The Web encoder 1003 converts the video signal into a digital video signal of a video data format such as JPEG or MPEG, and transmits the converted video signal to the video storage / delivery device 1005. In the video storage / delivery device 1005, the video signal received by the network interface 1103 is input to the CPU 1101, assigned an identification number by the CPU 1101, and then appropriately stored and stored in the storage device 1104 as video data.

Next, a method of delivering the video data stored in the video storage / delivery device 1005 to the browser PC 1006 or the portable terminal 1011 will be described.
The browser PC 1006 or the mobile terminal 1011 transmits a video data acquisition request signal to the video storage / delivery device 1005. The request for obtaining the video data is for obtaining a video signal representing desired video data by designating an identification number given to the video signal when storing the video data. The data acquisition request signal transmitted from the browser PC 1006 reaches the video storage / delivery device 1005 via the LAN transmission path 1002 and the hub 1004. The video storage / delivery device 1005 transmits a video signal corresponding to the identification number designated by the video acquisition request to the browser PC 1006. The transmitted video signal reaches the browser PC 1006 via the hub 1004 and the transmission path 1002 of the LAN. The browser PC 1006 converts the video signal into an analog video signal, inputs the analog video signal to the monitor 1109 via the video interface 1108, and displays a video based on the video signal.

  When a video data acquisition request signal similar to the above is transmitted from the mobile terminal 1011 to the video accumulation / delivery device 1005, the video data acquisition request signal is transmitted via the wireless transmission path 1010, the WAN 1009, and the public line 1008. The data is transmitted to the video browsing data conversion device 1007. The video browsing data conversion device 1007 converts the received video data acquisition request signal into a format that can be received by the video storage / delivery device 1005, and then transmits the converted signal. The video storage / delivery device 1005 extracts a video signal representing appropriate video data from the storage device 1104, and transmits the video signal to the video browsing data conversion device 1007. The video browsing data conversion device 1007 converts the received video signal from a signal in the format at the time of the reception to a signal in a format that the mobile terminal 1011 can display on the monitor 1109. Further, a protocol for a portable terminal is selected as a protocol for transmitting the video signal, and the format is converted to the format of the selected protocol. That is, the video browsing device 1007 is a device having a protocol conversion function and an image format conversion function between the portable terminal 1011 and the storage / distribution device 1005. The portable terminal 1011 converts the received video signal into an analog video signal, and displays a video based on the video signal on the monitor 1009. The browser PC 1006 and the portable terminal 1011 can receive two kinds of images, a past image accumulated in the image accumulation and distribution device 1005 and a latest image accumulated.

FIG. 24 is an explanatory diagram showing a procedure for storing a video image captured by the monitoring camera 1001 in the video storage / delivery device 1005.
In FIG.
(1) Step S1901 is a step of capturing an image using the monitoring camera 1001 and generating a video signal representing the image. After this step, a step of confirming the connection of the device used in step S1901 may be added. For example, if imaging is performed using the monitoring camera 1001, the process advances to step S1902; otherwise, this procedure ends or the process waits until the monitoring camera is connected.
(2) Step S1902 is a step in which the monitoring camera 1001 transmits the video signal to the Web encoder 1003.
(3) Step S1903 is a step in which the Web encoder 1003 converts the video signal into a digital video signal.
(4) Steps S1904 and S1905 are steps in which the Web encoder 1003 transmits the video signal to the video accumulation / delivery device 1005 via the hub 1004.
(5) Step S1906 is a step in which the video accumulation and distribution device 1005 stores the video signal in the storage device 1104 in the video accumulation and distribution device 1005.
By the above-described processing, the video signal of the video captured by the monitoring camera 1001 is stored as video data in the video storage / delivery device 1005.

FIG. 25 is a diagram showing a procedure for browsing the video data stored in the video storage / delivery device 1005 by the browser PC 1006 or the mobile terminal 1011.
The flowchart shown in FIG. 25 will be described below.
(1) Step S2001 is a step of transmitting a video data acquisition request signal to the storage and distribution device 1005 using the browser PC 1006.
(2) Steps S2002 and S2003 are steps in which the browser PC 1006 transmits the video data acquisition request signal to the video storage / delivery device 1005 via the hub 1004.
(3) Step S2004 is a step in which the video accumulation / delivery device 1005 extracts a video signal as video data from the storage device 1104 in accordance with the video data acquisition request signal.
(4) Steps S2005 and S2006 are steps in which the video accumulation / delivery device 1005 transmits the video signal to the browser PC 1006 via the hub 1004.
(5) Step S2007 is a step in which the browser PC 1006 displays an image based on the image signal on the monitor 1109.

FIG. 26 is a diagram showing a procedure for browsing the video data stored in the video storage / delivery device 1005 with the portable terminal 1011.
The flowchart shown in FIG. 26 will be described below.
(1) Step S2101 is a step of transmitting a video data acquisition request signal to the storage and delivery device 1005 using the mobile terminal 1011.
(2) Step S2102 is a step in which the mobile terminal 1011 transmits the video data acquisition request signal to the video browsing data conversion device 1007.
(3) Step 2103 is a step in which the video browsing data conversion device 1007 converts the protocol of the video data acquisition request signal into a protocol that can be interpreted by the video storage / delivery device 1005.
(4) Steps S2104 and S2105 are steps in which the video browsing data conversion device 1007 transmits the video data acquisition request signal to the video storage / delivery device 1005 via the hub 1004.
(5) Step S2106 is a step in which the video accumulation / delivery device 1005 extracts a video signal as video data from the storage device 1104 according to the video data acquisition request signal.
(6) Steps S2107 and S2108 are steps in which the video accumulation / delivery device 1005 transmits the video signal to the video browsing data conversion device 1007 via the hub 1004.
(7) Step S2109 is a step in which the video browsing data conversion device 1007 converts the format of the video signal into a format that the mobile terminal 1011 can display on the monitor 1109.
(8) Step S2110 is a step in which the video browsing data conversion device 1007 transmits the video signal to the mobile terminal 1011.
(9) Step S2111 is a step in which the mobile terminal 1011 receives the video signal and displays a video based on the signal on the monitor 1109.
As described above, the browser PC 1006 or the portable terminal 1011 allows the browser PC 1006 or the portable terminal 1011 to browse the video data stored in the storage delivery device 1005. The video browsing data conversion device 1007 can also transmit and receive audio signals, and can transmit and receive audio signals to and from the browser PC 1006 and the portable terminal 1011.

1 to 10 are explanatory diagrams of a first embodiment of the present invention.
In the present embodiment, a method of storing video captured by a mobile terminal with an imaging function in a storage and delivery device and delivering the video to a browser PC or another mobile terminal will be described.
FIG. 1 is a diagram showing an example of a network configuration of a device according to the present invention. As compared with the configuration shown in FIG. 22, a mobile terminal 101 with an imaging function, a video storage data converter 102, and an authentication server 1020 are added. The portable terminal 101 and the video storage data converter 102 are connected by a wireless transmission line 1010, a WAN 1009, and a public line 1008. The mobile terminal with imaging function 101 and the data conversion device for video storage 102 are computers having the hardware configuration shown in FIG.

FIG. 2 shows an example of a procedure in a method of storing a video signal representing a video image captured using the mobile terminal with imaging function 101 of FIG. 1 in the video storage / delivery device 1005 via the video storage data conversion device 102. FIG.
In FIG.
(1) In step S201, an image is captured using a camera for realizing the image capturing function of the mobile terminal 101 with an image capturing function, and a video signal as video data is generated.
(2) In step S202, communication between the portable terminal with imaging function 101 and the image storage / delivery device 1005 is established. At this time, the authentication server 1020 also performs an authentication operation on the mobile terminal 101 with an imaging function that can communicate with the video storage / delivery device 1005.
(3) In step S203, the video signal as the video data is transmitted from the mobile terminal 101 to the video accumulation / delivery device 1005.
(4) In step S204, the connection between the portable terminal with imaging function 101 and the video storage / delivery device 1005 is disconnected. At this time, before generating the video data in step S201, the connection between the mobile terminal with imaging function 101 and the video storage / delivery device 1005 may be established in step S202. That is, the order of step S201 and step S202 may precede either.

Here, a method of transmitting an image of a mobile terminal camera attached to the mobile terminal 101 (PDA, mobile phone, etc.) to the video storage / delivery device 1005 will be described below (see FIG. 3).
(1) Data of a captured video or still image is stored as a file in a storage area (memory or the like) in the portable terminal 101 (step 251).
(2) Using the electronic mail function of the portable terminal, the saved file is sent as an attached file of the electronic mail to the video storage data conversion device 102 having the electronic mail server function by the electronic mail communication protocol. (Step 252).
(3) The sent e-mail is received by the video storage data converter 102 by an e-mail server function (for example, a POP server) (step 253).
(4) The attached file of the electronic mail is extracted from the electronic mail by the program stored in the magnetic recording device of the video storage data converter 102 (step 254).
(5) The extracted attached file is further read from the data in the file, subjected to codec conversion and format conversion as necessary, and written into a storage area in the video storage data conversion device 102. At this time, the codec conversion and the format conversion are performed so as to have the same codec and format as when the surveillance camera provides the video to the video storage / delivery device (step 255).
(6) The data written in the storage area in the video storage data conversion device 102 is transmitted to the video storage / delivery device using the same communication protocol as when the monitoring camera 1001 distributes video to the video storage / delivery device 1005, for example, HTTP. 1005 (step 256).
(7) The distributed data is received and recorded by the video accumulation and distribution device 1005. Codecs are JPEG, MPEG1, 2, 4, H.264. 261, H .; 323 and the like. The basic structure of the format is codec + header information.

FIG. 4 is an explanatory diagram of the contents of step S202, and shows an example of a procedure in a method of establishing a connection between the portable terminal with imaging function 101 and the video storage and distribution device 1005 via the video storage data converter 102. FIG.
In FIG.
(1) The user authentication server is accessed from the browser PC in advance, and a user name and a password are input to a table as shown in FIG. 27 as user information stored in the storage device of the user authentication server.
(2) In step S301, a process for connecting the portable terminal with imaging function 101 and the video accumulation / delivery device 1005 is started.
(3) In step S302, a connection request signal is transmitted from the portable terminal with imaging function 101 to the data conversion device 102 for video storage. A user name of the user of the portable terminal 101 and a password are added to the connection request signal. The user of the portable terminal with imaging function 101 registers the user name and the password in the video storage data converter 102 in advance.
(4) In step S303, the video storage data converter 102 receives the connection request signal.
(5) In step S304, the video data converter 103 for video storage acquires a user name and a password from the user information S305. The user information 305 is a file for storing a user name and a password registered by the user of the mobile terminal 101 in the video storage data converter in advance. This file is stored in the storage device 1104 of the video storage data converter 102.
(6) In step S306, the user name included in the connection request signal received in step S303 is compared with the user name acquired from the user information 305 in step S304. If the two user names do not match, it is determined that the user who issued the connection request signal is an unauthorized person, and the process proceeds to step S313. If the two user names match, the process proceeds to step S307.
(7) In step S307, the password included in the connection request signal received in step S303 is compared with the password acquired from the user information 305 in step S304. Here, if the two passwords do not match, it is determined that the user who issued the connection request signal is an unauthorized user, and the process proceeds to step S313. If the two passwords match, the process proceeds to step S308.
(8) In step S308, the video storage data conversion device 102 transmits a connection request signal to the video storage / delivery device 1005.
(9) In step S309, the video accumulation and distribution device 1005 receives the connection request signal from the video accumulation data converter 102.
(10) In step S310, the storage and delivery apparatus 1005 transmits a result indicating whether the connection was successful or failed in response to the connection request signal to the video storage data conversion apparatus 102 as a connection result response signal.

(11) In step S311, the video accumulation data converter 102 receives the connection result response signal in step S310.
(12) In step S312, the video storage data converter 102 converts the connection result response signal received in step S311 into a format that can be interpreted by the portable terminal with imaging function 101 and transmits the signal.
(13) In step S313, the portable terminal with imaging function 101 receives the connection result response signal transmitted from the video storage data conversion device 102 in step S312.
(14) In step S314, the mobile terminal with imaging function 101 interprets the result response signal and determines a connection result. If it is determined that the connection has been made normally, the process proceeds to step S315. If it is determined that the connection has failed, the process proceeds to step S316.
(15) In step S315, it is determined that the connection between the mobile terminal with imaging function 101 and the video accumulation / delivery device 1005 has been normally terminated, and the connection process is terminated.
(16) In step S316, it is determined that the connection between the portable terminal with imaging function 101 and the video storage / distribution device 1005 has failed, and the fact that the connection has failed is displayed on the monitor of the portable terminal with imaging function 101, thereby providing the user with the information. Notice.
Reference numeral 317 denotes a boundary line display for clearly indicating the boundaries between the portable terminal with imaging function 101, the video storage data conversion device 103, and the video storage / delivery device 1005.

  In addition, for example, linking with an electronic authentication service “First Pass” (http://www.nttdocomo.co.jp/p_s/firstpass/) provided by DOCOMO using the PKI (Public Key Infrastructure) method for FOMA correspondence There are ways. In this case, since the user often forgets the ID and the password, it is possible to log in by inputting only one code (PIN2) in “First Pass”. The user authentication server verifies that the user certificate is issued by either DOCOMO or DOCOMO Group, and the ID is different from the telephone number that DOCOMO or DOCOMO Group assigns to the user for each FOMA service contract. Has a function to confirm the number.

FIG. 5 is an explanatory diagram of the contents of step S203, in which a video signal as video data generated by the portable terminal with imaging function 101 is transmitted to the video storage and distribution device 1005 via the video storage data conversion device 102. 9 is a flowchart illustrating an example of a procedure of a process of accumulating and storing.
In FIG.
(1) In step S401, a video accumulation process is started.
(2) In step S402, the mobile terminal with imaging function 101 transmits a video storage request signal to the video storage data converter 102. Here, the video accumulation request signal includes the video data generated in step S201.
(3) In step S403, the video storage data converter 102 receives the video storage request signal transmitted in step S402.
(4) In step S404, the video storage data converter 102 extracts the video data included in the video storage request signal, and performs codec conversion on the format of the extracted data into a format that can be stored by the video storage / delivery device 1005.
(5) Step S405 is a step of transmitting the video storage request signal to the video storage / delivery device 1005 using a protocol that can be interpreted by the video storage / delivery device 1005. At this time, the video data converted in step S404 is added to the video accumulation request signal.
(6) In step S406, the video accumulation / delivery device 1005 receives the video accumulation request signal transmitted in step S405.
(7) In step S407, the video accumulation and distribution device 1005 extracts the video data from the video accumulation request signal, and stores and accumulates the extracted data in the storage device 1104.
(8) In step S408, whether or not the video accumulation processing by the video accumulation / delivery device 1005 has been completed normally is transmitted to the video accumulation data conversion device 102 as a video accumulation result response signal.
(9) In step S409, the video storage data converter 102 receives the video storage result response signal transmitted in step S408.
(10) In step S410, the video storage data converter 102 converts the video storage result response signal transmitted in step S409 into a protocol that can be interpreted by the portable terminal with imaging function 101, and converts the signal. Send a signal.

(11) In step S411, the portable terminal with imaging function 101 receives the video accumulation result response signal transmitted in step S410.
(12) In step S412, it is determined (determined) whether or not the video storage is successful, based on the video storage result response signal received in step S411. If it is determined (determined) that the process is successful, the process proceeds to step S414. If it is determined (failed) that it has failed, the process proceeds to step S413.
(13) In step S413, the fact that the image storage has failed is displayed on the monitor of the portable terminal with imaging function 101. Thereby, the failure of the user of the portable terminal with imaging function 101 is clearly indicated.
(14) In step S414, the video accumulation processing ends.
Note that reference numeral 415 in FIG. 5 denotes a boundary line display that clearly indicates boundaries between the portable terminal 101, the video storage data conversion device 103, and the video storage / delivery device 1005.

FIG. 6 is an explanatory diagram of the contents of step S204, and shows an example of a procedure of a process of disconnecting the connection between the portable terminal with imaging function 101 and the video storage and distribution device 1005 via the video storage data converter 102. Show.
In FIG.
(1) In step S501, a disconnection process between the portable terminal with imaging function 101 and the video storage / delivery device 1005 is started.
(2) In step S502, the mobile terminal with imaging function 101 transmits a disconnection request signal to the video storage data converter 102.
(3) In step S503, the video storage data converter 102 receives the disconnection request signal transmitted in step S502.
(4) In step S504, the video storage data converter 102 converts the disconnection request signal into a protocol that can be interpreted by the storage and delivery device 1005, and transmits the converted signal.
(5) In step S505, the video accumulation / delivery device 1005 receives the disconnection request signal.
(6) In step S506, the video accumulation / delivery device 1005 transmits a disconnection result signal indicating a processing result for the disconnection request signal to the video accumulation data conversion device 102, and disconnects the connection with the video accumulation data conversion device 102.
(7) In step S507, the video storage data converter 102 receives the disconnection result signal.
(8) In step S508, the video storage data converter 102 converts the format of the disconnection result signal into a format that can be interpreted by the mobile terminal with imaging function 101, and transmits the converted signal.
(9) In step S509, the portable terminal with imaging function 101 receives the disconnection request signal transmitted in step S508.
(10) In step S510, it is determined (determined) whether or not the disconnection was successful based on the disconnection result signal. If it is determined (determined) that the disconnection has succeeded, the process proceeds to step S512. If it is determined that the disconnection has failed (determined), the process proceeds to step S511.

(11) In step S511, the fact that the disconnection processing has failed is displayed on the monitor 1109 of the portable terminal with imaging function 101 to clearly indicate to the user.
(12) In step S512, the cutting process ends.
In FIG. 6, reference numeral 513 denotes a boundary line display for clearly indicating the boundaries between the portable terminal 101, the video storage data conversion device 103, and the video storage / delivery device 1005.
According to the above-described method, the video data of the video captured by the mobile terminal with an imaging function 101 can be stored in the video storage / delivery device 1005 and distributed. The video data stored in the video storage / delivery device 1005 is distributed to the browser PC 1006 and the portable terminal 1011.
When a live image is being viewed on the browser PC 1006 or the mobile terminal 1011, a request is issued to the user of the mobile terminal 101 with an imaging function to give an instruction on the place where the image is captured. In order to respond to the above request, the data transmitted and received by the browser PC 1006, the video browsing data conversion device 1007, the mobile terminal 1011, the video storage data conversion device 102, and the mobile terminal 101 with an imaging function include not only video data but also audio data. Need to be able to handle

FIG. 7 is a diagram illustrating an example of a network configuration and a data flow when audio data can be transmitted and received. FIG. 7 further describes the types of data flowing through the respective transmission paths in addition to FIG.
In FIG. 7, audio data can be input and output by a browser PC 1006, a mobile terminal 1011, and a mobile terminal 101 with a video shooting function, and the audio data is distributed to each device via a hub 1004. Further, the video browsing data conversion device 1007 and the video storage data conversion device 102 convert the codec format of audio data and the protocol conversion process between the browser PC 1006 and the mobile terminal 1011 or the mobile terminal 101 with an imaging function. And a function of performing

FIG. 8 is an explanatory diagram of a case where audio data input from the browser PC 1006 is transmitted to the mobile terminal 101 with an imaging function.
In FIG.
(1) In step S701, the sound is converted into an audio signal by the microphone 1107 of the browser PC 1006, and the audio signal is output from the microphone 1107.
(2) In step S702, the browser PC 1006 receives the audio signal, and the audio signal is subjected to A / D conversion such as PCM to generate a digital audio signal.
(3) In step S703, the audio signal is transmitted to the browser PC 1006 via the LAN transmission path 1002 and the hub 1004.
(4) In step S704, the audio signal received by the video storage / delivery device 1005 is transmitted to the video storage data conversion device 102 via the LAN transmission path 1002. The audio data is also distributed to browser PCs 1006 other than browser PC 1006 that transmitted the audio signal. At this time, it is unnecessary to perform the codec conversion and the protocol conversion again, and the received audio signal may be distributed as it is to the browser PC 1006 other than the browser PC 1006 that transmitted the audio signal.
(5) In step S705, the portable terminal 101 with the imaging function receives the audio signal received by the video storage data conversion device 102, converts the signal format into a reproducible format, and converts the audio signal into a reproducible format. The signal is converted into a protocol that can be interpreted by the mobile terminal with imaging function 101, and the converted signal is transmitted. When there are a plurality of portable terminals with imaging function 101 to receive the audio signal, the audio signal is transmitted to each of them.
(6) In step S706, the portable terminal with imaging function 101 receives the audio data.
(7) In step S707, the audio signal received by the mobile terminal with imaging function 101 is converted into an analog audio signal by D / A conversion.
(8) In step S708, the analog audio signal is output as sound from the speaker 1106 in the portable terminal with imaging function 101.

FIG. 9 is a flowchart in the case where an audio signal is transmitted from the portable terminal with imaging function 101 to the browser PC 1006.
In FIG.
(1) In step S801, the sound is converted into an audio signal by the microphone 1107 of the portable terminal with imaging function 101, and the audio signal is output from the microphone 1107.
(2) In step S802, the portable terminal with imaging function 101 converts the audio signal from an analog signal to a digital audio signal.
(3) In step S803, the portable terminal 101 with the imaging function transmits the audio signal to the video storage data conversion device 102.
(4) In step S804, the transmitted audio signal is received by the video storage data converter 102. The received audio signal is converted into a format that the browser PC 1006 can receive and interpret. Further, the audio signal is converted into a protocol format that can be interpreted by the browser PC 1006, and the converted audio signal is transmitted to the browser PC 1006 via the hub 1004.
(5) In step S805, the received audio signal is transmitted to the browser PC 1006 via the hub 1004. If there are a plurality of browser PCs 1006 that receive the audio signal, the audio signal is transmitted to each of them.
(6) In step S806, the browser PC 1006 receives the audio signal.
(7) In step S807, the browser PC 1006 D / A converts the audio signal into an analog audio signal.
(8) In step S808, the audio signal is reproduced as audio from the speaker 1006 in the browser PC 1006.

  8 and 9, the case where an audio signal is transmitted from the browser PC 1006 to the mobile terminal 101 with an imaging function and the case where an audio signal is transmitted from the mobile terminal 101 with an imaging function to the browser PC 1006 have been described. 8 and 9 are also applicable to the case where the mobile terminal 1011 transmits and receives an audio signal. In this case, in step S704 in FIG. 8, it is assumed that the hub 1004 transmits and receives an audio signal to and from the video browsing data converter 1007. In step S705, the processing of the video storage data converter 102 is The data conversion device 1007 may perform the processing. Similarly, in step S803 in FIG. 9, it is assumed that the mobile terminal 101 transmits an audio signal to the video browsing data conversion device 1007, and in step S804, the processing of the video storage data conversion device 102 is performed by the video browsing data conversion device 1007. May go.

FIG. 10 is a configuration example diagram of an emergency system using the video storage technology and the audio transmission / reception technology.
In FIG. 10, 901 is a caller, 902 is a fire department, 903 is a hospital, and 904 is an ambulance. The reporter 901 has the mobile terminal 101 with an imaging function, and the fire department 902 has a video storage and delivery device 1005, a video browsing data conversion device 1007, a video storage data conversion device 102, a browser PC 1006, and an authentication server 1020. The hospital 903 has a browser PC 1006. The ambulance 904 includes a mobile terminal 1011 and the mobile terminal 101 with an imaging function. The video storage / delivery device 1005 of the fire department 902 is connected to the video storage data conversion device 102 and the video browsing data conversion device 1007 via a private LAN, and further connected to the browser PC 1006 of the hospital 903 via a LAN or a public line.

  In such a configuration, an operation from when an emergency patient is generated under the informant 901 and conveyed to the hospital 903 by the ambulance 904 will be described. First, the reporter 901 requests the fire department 902 to dispatch an ambulance. At this time, the reporter 901 reports to the fire department 902 using the portable terminal 101 with an imaging function. Then, the state of the patient is imaged by the portable terminal with imaging function 101, and the obtained video signal is transmitted to the fire department 902. The transmitted video signal can be browsed by the browser PC 1006 in the fire department 902 and the browser PC 1006 in the hospital 903 via the video storage data converter 102 and the video storage and distribution device 1005 in the fire department 902. In the hospital 903, a doctor considers a countermeasure method such as a measure for a patient while watching an image based on the image signal. When the doctor records a voice from the microphone 1107 of the browser PC 1006, a voice signal corresponding to the voice is delivered to the portable terminal with imaging function 101, that is, the reporter 901 by the processing described in FIG. It is possible to give an instruction such as the direction of the camera of the portable terminal with imaging function 101 and the emergency measure method to the notifier 901 by voice. Furthermore, the video can be viewed on the mobile terminal 1011 in the ambulance 904 heading to the site, and necessary measures can be considered.

  When the ambulance 904 arrives at the reporter 901, the portable terminal 101 with the imaging function in the ambulance 904 or the portable terminal 101 with the imaging function of the reporter 901 continues to use the browser of the hospital 903 via the fire department 902. A video signal obtained by imaging the state of the patient and the like is transmitted to the PC 1006. Thus, the doctor in the hospital 903 can check the state of the patient in the ambulance 904 with the image, and can give a voice instruction to the rescue personnel in the ambulance 904. When the patient is transported to the hospital 903, the necessary measures and tools are already prepared, so that prompt response is possible. Further, since the video data during the transportation of the patient is stored in the video storage / delivery device 1005 and can be reproduced at any time therefrom, the state of the patient can be confirmed by referring to the past video as necessary. it can. As a result, video information can be obtained from information that was conventionally obtained only by voice, thereby enabling quicker and more accurate response than before.

  Although the above application example was described as a system connecting fire departments, ambulances, hospitals, and whistleblowers, similar systems can be applied to government agencies such as police stations, fire departments, local governments, and media organizations such as television stations and newspaper companies. is there. For example, in local governments, the above system can be applied for monitoring and reporting abnormalities such as dams and power plants, and in media organizations, the first report of images taken by ordinary people using mobile terminals The above system can be applied when receiving. In addition, if applied to police stations, it will be possible to use the video reports from citizens as evidence to help resolve cases faster. Furthermore, according to the above system, since video data and audio data can be distributed to a plurality of devices from a remote location, a person at a remote location can be distributed based on video and audio from a mobile terminal with an imaging function. It is also possible to realize a TV conference system that connects the two. In addition, since the video data from the mobile terminal 101 with an imaging function is stored in the video storage and distribution device 1005, the video data may be stored and displayed as a video message board or a video library. These can be installed, for example, in a public hall or the like and used for exchanging information with local residents.

  According to the first embodiment, it is possible to easily capture image data of a blind spot of a surveillance camera having a blind spot, video data of a place where there is no surveillance camera, and the like. It can be distributed.

FIGS. 11 to 21 are explanatory diagrams of the second embodiment of the present invention.
FIG. 11 is a diagram illustrating an example of a network configuration. The configuration of FIG. 11 is different from the configuration of FIG. 1 in that a portable monitoring camera 1013, a wireless transmission path 102, and a wireless hub 103 are newly added.
In FIG. 11, a portable surveillance camera 1013 and a wireless hub 103 are connected via a wireless transmission path 1010. The wireless hub 103 is connected to a hub 1004 of a network-type monitoring system via a LAN transmission line 1002. Note that the portable surveillance camera 1013 has a built-in Web encoder.

  In the embodiment shown in FIG. 1, after the authentication server performs the authentication work with the mobile terminal, data is transmitted and received between the mobile terminal and various servers. This is for transmitting and receiving data to and from a specific authenticated terminal. On the other hand, in the embodiment shown in FIG. 11, when data is transmitted and received between the portable monitoring camera and various servers, the authentication work by the authentication server may be omitted. This is because the portable surveillance camera is located in the same LAN as the various servers, so that communication management for the portable surveillance camera can be realized relatively easily than communication management for the portable terminal without using an authentication server.

FIG. 12 is a diagram illustrating an example of a hardware configuration inside the portable monitoring camera 1013.
12, 3001 is a camera unit, 3002 is a Web encoder unit, 3003 is a microphone, 3004 is an A / D converter, 3005 is an audio encoder unit, 3006 is a speaker, 3007 is a D / A converter, and 3008 is audio. A decoder unit, 3009 is a wireless unit, and 3010 is a bus. The units 3001 to 3009 are connected to each other via a bus 3010, and the wireless unit 3009 can transmit and receive data to and from the wireless hub 103 via a wireless transmission path 1010. The camera unit 3001 has a function equivalent to that of the conventional monitoring camera 1001, captures an image, and outputs a video signal. The Web encoder unit 3002 has a function equivalent to that of the conventional Web encoder 1003, and converts the video signal into a digital video signal. The microphone 3003 records voice and converts it into a voice signal. The A / D converter 3004 converts the converted audio signal (analog audio signal) into a digital audio signal. The audio encoder unit 3005 converts the digital audio signal into an audio signal in a format that can be transmitted and received among the browser PC 1006, the video browsing data converter 1007, and the video storage data converter 1012. The speaker 3006 reproduces sound according to the input sound signal. D / A converter 3007 converts a digital audio signal into an analog audio signal. The audio decoder unit 3008 converts an audio signal in a format that can be transmitted and received between the browser PC 1006, the video browsing data converter 1007, and the video storage data converter 1012 into an audio signal that can be converted by the D / A converter 3007. Convert. The wireless unit 3009 transmits and receives a video signal and an audio signal to and from the wireless hub 103 via a wireless transmission path 1010.

FIG. 13 is an explanatory diagram of a method of storing video data in the storage and delivery device 1005.
In FIG.
(1) In step S4001, the camera unit 3001 of the portable monitoring camera 1013 captures an image, generates a video signal, and transmits the video signal to the Web encoder unit 3002.
(2) In step S4002, the Web encoder unit 3002 converts the video signal into a digital video signal, and the converted signal is transmitted to the wireless unit 3009.
(3) In step S4003, the wireless unit 3009 that has received the video signal transmits the received video signal to the wireless hub 103.
(4) In step S4004, the wireless hub 103 that has received the video signal transmits the received video signal to the hub 1004.
(5) In step S4005, the hub 1004 that has received the video signal transmits the received video signal to the video accumulation / delivery device 1005.
(6) In step S4006, the video accumulation / delivery device 1005 that has received the video signal stores the received video signal in the storage device 1104.
Through the above processing, the video data of the video captured by the portable monitoring camera 1013 can be stored in the video storage / delivery device 1005.

FIG. 14 is an explanatory diagram of a method of distributing audio data of audio recorded by the portable monitoring camera 1013 to the browser PC 1006.
(1) In step S5001, sound is recorded by the microphone 3003 of the portable monitoring camera 1013, and the sound signal obtained by the recording is transmitted from the microphone 3003 to the A / D converter 3004.
(2) In step S5002, the A / D converter 3004, which has received the audio signal, converts the audio signal (analog audio signal) into a digital audio signal, and transmits the converted audio signal to the audio encoder 3005. Is done.
(3) In step S5003, the audio encoder 3005 that has received the audio signal converts the audio signal format into a format that can be received by the browser PC 1006, the video browsing data conversion device 1007, and the video storage data conversion device 1012, that is, Is converted into a format handled by the network type monitoring system, and the converted audio signal is transmitted to the radio unit 3009.
(4) In step S5004, the wireless unit 3009 that has received the audio signal transmits the received audio signal to the wireless hub 103.
(5) In step S5005, the wireless hub 103 that has received the audio signal transmits the received audio signal to the hub 1004.
(6) In step S5006A, the hub 1004 that has received the audio signal transmits the received audio signal to the browser PC 1006.
(7) In step S5007A, the browser PC 1006 receives the audio signal via the network interface 1103.
(8) In step S5008A, in the browser PC 1006, the format of the received audio signal is converted by the sound interface 1105 into a format for audio reproduction by the speaker 1106.
(9) In step S5009A, the browser PC 1006 reproduces sound from the speaker 1106 based on the converted sound signal.

FIG. 15 is an explanatory diagram of a method of distributing audio data of audio recorded by the portable surveillance camera 1013 to the mobile terminal 1011. Steps S5001 to S5005 are the same as those described above, and thus the following step S5006B will be described.
(6) In step S5006B, the hub 1004 that has received the audio signal transmits the received audio signal to the video browsing data conversion device 1007.
(7) In step S5007B, the video browsing data conversion device 1007 receives the audio signal via the network interface 1103. (8) In step S5008B, the format of the received audio signal is converted to a format that can be received by the mobile terminal 1011 in the video browsing data conversion device 1007, and the converted audio signal is transmitted to the mobile terminal 1011. You.
(9) In step S5009B, the mobile terminal 1011 receives the audio signal via the network interface 1103.
(10) In step S5010B, in the portable terminal 1011, the format of the received audio signal is converted by the sound interface 1105 into a format for audio reproduction by the speaker 1106.
(11) In step S5011B, the portable terminal 1011 reproduces sound from the speaker 1106 using the converted sound signal.

FIG. 16 is an explanatory diagram of a method of distributing audio data of audio recorded by the portable surveillance camera 1013 to the mobile terminal 101 with an imaging function. Steps S5001 to S5005 are the same as those described above, and thus the following step S5006C will be described.
(6) In step S5006C, the received audio signal is transmitted to the video storage data converter 1012.
(7) In step S5007C, the video storage data conversion device 1012 receives the audio signal via the network interface 1103.
(8) In step S5008C, the format of the received audio signal is converted into a format that can be received by the mobile terminal with imaging function 101 in the video storage data conversion device 1012. The converted audio signal is transmitted to the mobile terminal 101 with an imaging function.
(9) In step S5009C, the portable terminal with imaging function 101 receives the audio signal via the network interface. (10) In step S5010C, the format of the received audio signal in the portable terminal with imaging function 101 is converted into a format for audio reproduction by the sound interface 1105 and the speaker 1106.
(11) In step S5011C, the portable terminal with imaging function 101 reproduces sound from the speaker 1106 based on the converted sound signal.
According to the method described above, it is possible to distribute the voice input to the portable monitoring camera 1013 to the browser PC 1006, the mobile terminal 1011 and the mobile terminal 101 with an imaging function.

FIG. 17 is an explanatory diagram of a method of reproducing the sound recorded by the browser PC 1006 by the portable surveillance camera 1013.
(1) In step S1401A, audio is recorded by the microphone 1107 of the browser PC 1006, and an audio signal obtained by the recording is output from the microphone 1107.
(2) In step S1402A, the browser PC 1006 inputs the output audio signal through the sound interface 1105, and converts the audio signal into a digital audio signal there.
(3) In step S1403A, the browser PC 1006 converts the format of the converted digital audio signal into an audio signal format handled by the network monitoring system, and the converted audio signal is transmitted to the hub 1004.
(4) In step S1405, the hub 1004 receives the above-described audio signal transmitted from at least one of the browser PC 1006, the mobile terminal 1011 and the mobile terminal with an imaging function 101, and transmits the received audio signal to the wireless hub 103. Sent to.
(5) In step S1406, the wireless hub 1004 that has received the audio signal transmits the received audio signal to the portable monitoring camera 1013.
(6) In step S1407, the portable monitoring camera 1013 receives the transmitted audio signal via the wireless unit 209, and outputs the received audio signal from the wireless unit 2 to the audio decoder unit 3008. .
(7) In step S1408, the audio decoder unit 3008 that has input the audio signal converts the format of the input audio signal into a format that can be processed by the D / A converter 3007, and converts the converted audio signal. The signal is output to D / A conversion section 3007.
(8) In step S1409, the D / A converter 3007 that has input the audio signal converts the input audio signal into an analog audio signal, and the converted analog audio signal is transmitted to the speaker 3006.
(9) In step S1410, the speaker 3006, to which the analog audio signal has been input, reproduces audio by the input analog audio signal.
According to the above method, the sound input from the browser PC 1006 can be reproduced by the monitoring camera 1013.

FIG. 18 is an explanatory diagram of a method of reproducing sound recorded by the portable terminal 1011 by the portable surveillance camera 1013.
(1) In step S1401B, sound is recorded by the microphone 1107 of the portable terminal 1011, and a sound signal obtained by the recording is output from the microphone 1107.
(2) In step S1402B, the portable terminal 1011 receives the output audio signal via the sound interface 1105, and converts the audio signal into a digital audio signal there.
(3) In step S1403B, the mobile terminal 1011 converts the format of the converted digital audio signal into a format of an audio signal handled by the mobile terminal 1011. The converted audio signal is converted to a video browsing data conversion device. 1007.
(4) In step S1404B, the video browsing data conversion device 1007 that has received the audio signal converts the format of the received audio signal into a format that can be received by the portable monitoring camera (a format handled by the network monitoring system). The converted audio signal is transmitted to the hub 1004.
Hereinafter, steps S1405 to S1410 are executed in the same manner as described above.
According to the above method, the sound input from the mobile terminal 1011 can be reproduced by the monitoring camera 1013.

FIG. 19 is an explanatory diagram of a method of reproducing the sound recorded by the portable terminal with imaging function 101 by the portable surveillance camera 1013.
(1) In step S1401C, audio is recorded by the microphone 1107 of the portable terminal with imaging function 101, and an audio signal obtained by the recording is output from the microphone 1107.
(2) In step S1402C, in the portable terminal with imaging function 101, the output audio signal is input through the sound interface 1105, and the audio signal is converted into a digital audio signal there.
(3) In step S1403C, the mobile terminal with imaging function 101 transmits the converted digital audio signal to the video storage data conversion device 1012.
(4) In step S1404C, the video storage data conversion device 1012 that has received the audio signal converts the format of the received audio signal into a format that can be received by the portable monitoring camera 1013 (a format handled by the network monitoring system). , And the converted audio signal is transmitted to the hub 1004.
Thereafter, steps S1405 to S1410 are executed as in the above case.
According to the above-described method, the sound input from the portable terminal with imaging function 101 can be reproduced by the monitoring camera 1013.

FIG. 20 and FIG. 21 are explanatory diagrams of a configuration example of a network type monitoring system using the portable monitoring camera 1013.
FIG. 20 is a diagram illustrating an application example of the above system in a fire department. It should be noted that it is easy to compare with the system shown in this figure, and as another system related to the present invention, there is an emergency system shown in FIG. 10 described above. In FIG. 20, 601 is a caller, 602 is a fire department, 603 is a hospital, and 604 is an ambulance. The reporter 601 has the portable terminal 101 with an imaging function. The fire department 602 has a network type monitoring system, and has a wireless hub 103, a video browsing data conversion device 1007, a video storage data conversion device 1012, a video storage and distribution device 1005, a browser PC 1006, and an authentication server 1020. . The hospital 603 has a browser PC 1006. The browser PC 1006 in the hospital 603 is connected to a network type monitoring system of the fire department 602 by a LAN or a public line. The ambulance 604 includes a portable terminal 1011 and a portable monitoring camera 1013. The portable terminal 1011 and the portable surveillance camera 1013 of the ambulance 604 are connected to a network-type surveillance system of the fire department 602 via a LAN, a public line, or wirelessly.

  In such a system configuration, when an emergency patient is generated under the informant 601, the informant 601 requests the fire department 602 to dispatch an ambulance using the portable terminal 101 with an imaging function, and images the state of the emergency patient. Then, the obtained video signal is transmitted to the network type monitoring system in the fire department 602. By doing so, the video based on this video signal can be displayed and browsed on the browser PC 1006 of the fire department 602 and the hospital 603 and the portable terminal 1011 of the ambulance 604. Further, the video signal is stored in the video storage and delivery device 1005. In the hospital 603, the doctor can determine emergency measures based on the displayed image using the browser PC1006. At this time, the doctor can give an instruction such as an emergency measure method and an angle adjustment of the portable terminal 101 with an imaging function to the caller 601 by voice. As a result, appropriate emergency measures can be taken, and a desired image of a doctor can be obtained. In addition, since the image can be viewed on the portable terminal 1011 of the ambulance 604, the rescue squad can quickly determine a measure.

While the ambulance 604 arrives at the caller 601 and puts the patient on the way to the hospital 603, the ambulance 604 uses the portable surveillance camera 1013 to capture an image of the patient, and obtains an image. A signal can be transmitted to the hospital 603. The video based on the video signal has higher image quality than the video based on the video signal obtained by the mobile terminal 101 with an imaging function, and the doctor can further determine an appropriate measure based on the higher quality video. . At this time, it is possible for the doctor to give an instruction to the rescue worker using the portable monitoring camera 1013 by voice. In the treatment of the emergency patient, the doctor can recognize the change in the condition by playing back the video stored in the video storage / delivery device 1005, and thereby can perform the measure more accurately.
According to the above, since the video data is added in addition to the audio data, the amount of information is further increased, so that a more accurate treatment can be performed more quickly than before.

  FIG. 21 is an explanatory diagram in the case where the above system is applied to a police station. In FIG. 21, 701 and 702 are police cars, and 703 is a police station. The police car 701 has a portable monitoring camera 1013, the police car 702 has a portable terminal 1011 and the police station 703 has a network monitoring system. Now, it is assumed that the police car 701 is tracking a running vehicle. Using the portable monitoring camera 1013 of the police car 701, an image of the vehicle is captured. The video signal representing the captured video is transmitted to the network type monitoring system of the police station 703, and the police station 703 can browse the video based on the transmitted video signal using the browser PC 1006.

  At this time, since information such as a vehicle type and a number is included in the video, it is possible to quickly identify the owner of the vehicle based on the information. When the police car 701 makes a support request to the police car 702, a voice instruction for transmitting the current position and the like from the police car 701 to the police car 702 via the portable monitoring camera 1013 and the portable terminal 1011. Can be given. Further, since the video signal is transmitted from the network-type monitoring system of the police station 703 to the portable terminal 1011 of the police car 702, the video of the transmitted video signal can be viewed on the police car 702 side. When the police car 702 arrives at the airport, the policeman on board the police car 702 can easily find the vehicle. Further, since the video data is stored in the video storage / delivery device 1005 of the police station 703, it can be recorded and held as definitive evidence of a violation.

  According to the above, at the police station 703, quick and accurate tracking can be performed. Further, since the video at the time of occurrence of the incident can be left in the video storage / delivery device 1005, it can be used as evidence later.

  Although the above example has been described for a case where the present invention is applied to a fire station and a police station, a similar system can also be applied to, for example, a local government or a media agency. In addition, since audio data input from the portable surveillance camera 1013 is distributed to the browser PC 1006, the portable terminal 1011 and the portable terminal 101 with an imaging function, a video conference system or the like is performed based on the video imaged by the portable surveillance camera 1013. Is also possible.

  According to the second embodiment as well, the surveillance camera can easily capture an image of a blind spot or a place where there is no surveillance camera, and the captured image data can be stored and distributed together with the audio data. . As a result, a wide range of information can be accurately and promptly used.

FIG. 1 is a diagram illustrating a network configuration example as a first embodiment of the present invention. FIG. 4 is an explanatory diagram of a method of storing video data obtained by imaging with a mobile terminal having an imaging function in a video accumulation and distribution device. FIG. 4 is an explanatory diagram of a method of storing video data obtained by imaging with a mobile terminal having an imaging function in a video accumulation / delivery device. FIG. 7 is a diagram illustrating an example of a procedure for establishing a connection between a mobile terminal and a video accumulation / delivery device. FIG. 3 is an explanatory diagram of transmitting and storing video data generated by a mobile terminal to a video storage and delivery device. FIG. 9 is a diagram illustrating an example of a procedure of a process of disconnecting a connection between a mobile terminal and a video accumulation / delivery device. FIG. 2 is a diagram illustrating a network configuration and a data flow capable of transmitting and receiving voice data. FIG. 3 is an explanatory diagram in a case where audio data is transmitted from a browser PC to a mobile terminal with an imaging function. FIG. 3 is an explanatory diagram in a case where audio data is transmitted from a portable terminal with an imaging function to a browser PC. 1 is a configuration example diagram of an emergency system using a video storage technology and a voice transmission / reception technology. 1 is a configuration example diagram of an emergency system using a video storage technology and a voice transmission / reception technology. It is a figure showing the example of hardware constitutions of a portable surveillance camera. FIG. 4 is an explanatory diagram of storing video data in a storage and delivery device. FIG. 3 is an explanatory diagram for distributing audio data to a browser PC or the like. FIG. 3 is an explanatory diagram for distributing audio data to a browser PC or the like. FIG. 3 is an explanatory diagram for distributing audio data to a browser PC or the like. FIG. 3 is an explanatory diagram for reproducing audio data with a portable surveillance camera. FIG. 3 is an explanatory diagram for reproducing audio data with a portable surveillance camera. FIG. 3 is an explanatory diagram for reproducing audio data with a portable surveillance camera. It is a figure showing an example of application to a fire department of a network type monitoring system. It is a figure showing an example of application of a network type monitoring system to a police station. FIG. 1 is a diagram illustrating a configuration example of a network monitoring system. FIG. 23 is a diagram illustrating an example of a hardware configuration of a video accumulation / delivery device in FIG. 22. FIG. 4 is an explanatory diagram of a procedure for storing video data in a video storage and delivery device. FIG. 4 is an explanatory diagram of a procedure for storing video data in a video storage and delivery device. FIG. 9 is an explanatory diagram of a procedure for browsing video data stored in the video storage and delivery device. FIG. 6 is a diagram illustrating an example of a user authentication server name / password table used in the authentication server.

Explanation of reference numerals

101: portable terminal with imaging function,
102 ... Data conversion device for video storage,
305: user information file,
901… reporter,
902 ... fire department,
903 ... hospital,
904 ... ambulance,
1001 ... surveillance camera,
1002: LAN transmission path,
1003 ... Web encoder,
1004 ... Hub,
1005 ... Video storage and delivery device,
1006 ... Browser PC,
1007: Data converter for video browsing,
1008: Transmission line by public line,
1009… WAN,
1010: wireless transmission path,
1011: portable terminal,
1101 ... CPU,
1102 ... memory,
1103: Network interface,
1104 storage device,
1105 ... Sound interface,
1106 ... speaker,
1107: Mike,
1108 video interface,
1109 Monitor
1110 ... input interface,
1111: input device,
1112: Pointing device.

Claims (5)

In a video data distribution system that distributes video data via a network,
An information terminal device that generates and transmits video data by at least a mobile terminal with an imaging function,
An authentication server unit having an authentication table for authenticating the mobile terminal with an imaging function,
A data conversion device that converts video data generated by the information terminal device into storable video data,
A video storage and delivery device that stores video data from the mobile terminal with an imaging function authenticated by the authentication table,
A video data distribution system configured to distribute video data stored in the video accumulation / delivery device to the information terminal device based on a distribution request from the information terminal device.   The video data distribution system according to claim 1, wherein the information terminal device includes a monitoring camera device.   The authentication server unit registers at least the ID number of the mobile terminal with an imaging function in the authentication table, and the mobile terminal with an imaging function stores video data corresponding to the ID number in the video storage and distribution device. 3. The video data distribution system according to claim 2, wherein   When distributing the stored video data to the information terminal device, the video storage / delivery device determines whether or not the information terminal device is registered in the authentication table, and distributes the data based on the determination result. The video data distribution system according to claim 1, wherein A video data distribution method for distributing video data via a network,
Generating video data in an information terminal device having a mobile terminal with an imaging function, and transmitting the generated video data;
Authenticating the mobile terminal with an imaging function using an authentication table;
Converting video data generated by the mobile terminal with an imaging function into storable video data;
Storing video data from the authenticated mobile terminal with an imaging function;
Distributing the video data stored in the video accumulation / delivery device to the information terminal device based on a distribution request from the information terminal device;
A video data distribution method characterized by distributing video data according to (1).

Images