Patent Publication Number: US-2017353647-A1

Title: Method and Apparatus for Live Capture Image-Live Streaming Camera

Description:
CROSS REFERENCE OF RELATED APPLICATION 
     This is a Continuation application that claims the benefit of priority under 35 U.S.C.§120 to a non-provisional application, application Ser. No. 13/199,559, filed Sep. 2, 2011, which is a Continuation-In-Part application that claims the benefit of priority under 35 U.S.C.§120 to a non-provisional application, application Ser. No. 12/583,299, filed Aug. 17, 2009. 
    
    
     NOTICE OF COPYRIGHT 
     A portion of the disclosure of this patent document contains material which is subject to copyright protection. The copyright owner has no objection to any reproduction by anyone of the patent disclosure, as it appears in the United States Patent and Trademark Office patent files or records, but otherwise reserves all copyright rights whatsoever. 
     BACKGROUND OF THE PRESENT INVENTION 
     Field of Invention 
     The present invention relates to a method and apparatus for image capture, and more particularly to a live image capture device which output is directly accessible by Internet users without the installation of proprietary software. 
     Description of Related Arts 
     Live image capture devices, commonly known as cameras, are used to record images. These images can then be perused in situations with a different time and place than where the image was taken. Because of these benefits and the advances in technology that have made cameras ubiquitous and available to most of the general public, cameras are widely used in modern society. 
     An example of the prevalence of cameras is the wide usage of cameras for security by both public and private institutions. In a scenario where an area needs to be continuously be monitored, cameras are often more suited for the job than humans, since images are recorded onto a hard medium and are viewable by others as long as the medium is maintained. 
     However, a camera by itself will most likely have just one function—capturing the image. One or more controllers must be employed to collect the data that is produced by the camera. In complex systems involving a multitude of cameras, the amount of resources required to maintain such a system increases significantly, and thus places limits on the efficiency of the system based on the available resources of the system&#39;s operator. 
     In such a system, high costs are accrued through the installation of the system itself. In a typical operation involving the installation of the system, the controller needs to be installed and secured. Then, the cameras themselves need to be installed in their respective positions, and a path of data transfer must be established between the cameras and the controller. Then, the interface of the system needs to be modified and adjusted to suit the operator&#39;s specifications, and so forth. This system cannot be very easily modified, and thus is limited in terms of flexibility. 
     The application of such systems is also limited by the medium upon which data is exchanged between the cameras and the controllers. Many existing camera-controller systems utilize wired networks in order to transfer data between the two. A well-known example of this is CCTV, where a signal from a camera is not openly transmitted, but broadcast to authorized controllers within the system. More modern systems employ Ethernet networks, such as the Internet, to transfer data. 
     Using the Internet protocol is highly advantageous, since most electronic devices today can in some way interact with this method of data transfer. However, the rate of data transfer in current systems is bottlenecked by the physical layer of the network infrastructure provided by the network service provider. An example of this is the fact that the current most popular network carriers, DSL and Internet cable, are only capable of uploading 1.5 Mb/s at maximum, which is hardly enough to transfer a high quality, high resolution video stream without delay. 
     A conventional way of solving this problem has been the act of video compression. This method has been widely used, but is not without its drawbacks. First, in order to compress video images transmitted by a camera, developers must create algorithm and codes for compression. This results in the creation of a plethora of compression codes, most incompatible with each other, in the market today. 
     Even when compression codes are relatively similar, minor differences in compression code from different providers can result in incompatibility. Consumers wishing to view electronic media must often face the daunting task of finding the correct decoding codec to match the code that the media was compressed with. 
     Another issue is currently used live video format is not editable. It is difficult to edit the display when the image is displayed lively. 
     Regarding the issues relating to current methods of image capture and transfer, there appears to be a need for the direct capture and transfer of images through a network. 
     SUMMARY OF THE PRESENT INVENTION 
     The present invention involves a method and apparatus for the live capture of images and the direct transfer of the aforementioned electronically through an Internet network. 
     The present invention integrates a control circuit apparatus onto the motherboard of an image capture device. The onboard control circuit apparatus receives data from the image capture device, and converts the data into a standard format. The control circuit apparatus also acts as built-in a web server, providing a network interface to connect with the Internet, and continuously updates itself with new data transmitted from the image capture device. Users can then use the Internet to directly access the data from the image capture device by accessing the web server provided by the control circuit apparatus. 
     The present invention presents a method to transfer image information. When the image capture device records an image, the control circuit apparatus transfers the image data onto its own web server directly. Thus, this eliminates the need for an intermediate network between the camera itself and the controller. The control circuit apparatus will also contain an interface for modification of data transmittance, adjustable to the operator&#39;s specifications. 
     In order to avoid format incompatibility, the web server only transfers still image files in standard formats (such as JPEG, PNG, GIF, et cetera), and thus frees both the server- and user-side operators from the process of compression. Movement, or video, is simulated by the transfer of multiple still image files over a short interval of time. 
     The main object of the present invention is to provide a method and apparatus for an image capture device that is accessible in real-time. 
     Another object of the present invention is to provide a method and apparatus for live capture image which is easy to be connected with a network. 
     Another object of the present invention is to provide a method and apparatus for live capture image which doesn&#39;t does not require a separate controller. 
     Another object of the present invention is to provide a method and apparatus for live capture image which is easy to install. 
     Another object of the present invention is to provide a method and apparatus for live capture image which reduces the required resources to install the method and apparatus itself. 
     Another object of the present invention is to provide a method and apparatus for live capture image which is convenient to operator. 
     Another object of the present invention is to provide a method and apparatus for live capture image which is remote controllable. 
     Another object of the present invention is to provide a method and apparatus for live capture image which supports simultaneous viewing of multiple channels. 
     Another object of the present invention is to provide a method and apparatus for live capture image which provides high quality live images. 
     Another object of the present invention is to provide a method and apparatus for live capture image which image is editable. 
     Another object of the present invention is to provide a method and apparatus for live capture image which reduces the amount of required storage media to hold output data. 
     To accomplish the above objects, the present invention provides an apparatus for live capture image accessible though a network, comprising: 
     a housing; 
     an image capture device for capturing image information; 
     a control circuit electrically connected with the image capture device and communicatively connected with the network for converting the image information captured by the image capture device into predetermined image data and transferring the image data through the network, wherein the image capture device and the control circuit are received by the housing. 
     The present invention also provides a method for capture live image, comprising steps of: 
     (a) frequently capturing live image information with a predetermined capture interval by one or more live image providers; 
     (b) converting the live image information to a still image file in a web based viewable format; 
     (c) continuously transferring the converted still image files to a platform via Internet; and 
     (d) obtaining the converted still image files at the platform to form a real time video like image at a predetermined frame rate by continuously overwriting the previous live image information with the latest live image information, so as to allow web browsers to watch the real time video like image without any proprietary software. 
     These and other objectives, features, and advantages of the present invention will become apparent from the following detailed description, the accompanying drawings, and the appended claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic view of a live capture image apparatus according to a preferred embodiment of the present invention. 
         FIG. 2  is a sectional view of a live image provider according to the above preferred embodiment of the present invention. 
         FIG. 3  is a schematic view of the live capture image system of the present invention. 
         FIG. 4  is a flow chart of the method for transferring live images according to the above preferred embodiment of the present invention. 
         FIG. 5  is a flow chart illustrating the live images transferring system according to a second embodiment of the present invention. 
         FIG. 6  is a block diagram illustrating the live images transferring system according to the above second embodiment of the present invention. 
         FIG. 7  illustrates the embed code being “copy-and-paste” from the control center to the personal website for broadcasting the live image information according to the above second embodiment of the present invention. 
         FIG. 8  illustrates an interface of the control center of the system according to the above second embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The present invention provides an apparatus for live capture image which is able to communicate with internet directly. Referring to  FIGS. 1 and 2  of the drawings, a preferred embodiment of the present invention is illustrated, wherein an apparatus for providing live image, which is a live image provider, comprises a housing  10 , an image capture device  20 , and a control circuit  30 . 
     The housing  10  is adapted for securely mounting at a predetermined location to securely receive the image capture device  20  and the control circuit  30 . Referring to  FIG. 2 , the housing  10  thoroughly covers the image capture device  20  and the control circuit  30  to provide protection. Therefore, the sensitive components such as the image capture device  20  and the control circuit  30  are able to work normally in a large range of environment. The housing  10  also comprises a window  11  made of transparent material in front of the lens  21  of the image capture device  20 , so light can transfer through the window  11  to reach the lens. 
     The image capture device  20  is adapted to capture image information and converts the captured image information into electronic signals. Preferably, an image capture device  20  comprises a lens  21  to capture light waves from a predetermined area, and an optical sensor  22  to convert the light waves into electronic signals. The electric signals can be transferred and processed later to reproduce the image by display devices, such as a computer monitor. 
     The image can be captured in different manners for different purposes. The image capture device  20  may take snapshot, which means capturing only one slide of image in a predetermined period of time. The image capture device  20  may take video, which means capturing a serial of slides of image in a short period of time, or in other words, taking snapshots continuously and frequently with short snapshot interval. Depending on the requirement, the image capture device  20  is able to provide different numbers of slides of image with different intervals. 
     Many techniques are appreciated to be applied in the image capture device  20  by whom skilled in the art. The embodiment of the present invention preferably utilizes but not limited to CCTV (Closed Circuit Television). In an alternative embodiment of the present invention, the apparatus for live capture image comprises more then one image capture devices to provide multiple channels of images. Therefore the user can accept multiple images simultaneously or alternatively. 
     The control circuit  30  comprises a processor  31 , a memory  32 , and a network interface  33 . The control circuit  30  is electrically connected with the image capture device  20  to receive the electronic signals produced by the image capture device  20 . The signals are converted into predetermined format, which is a web based viewable format, by the processor  31 . The file format includes image file such as JPEG, and video file such as MP4, FLV, and MPEG. These files are stored in the memory  32 . In a preferred embodiment, the image capture device  20  takes snapshots continuously and frequently with predetermined snapshot interval and resolution. The control circuit  30  converts the information of the snapshot into JPEG image files continuously and frequently and stores the image file in the memory  32 . It is worth mentioning, the memory  32  is always refreshed by the latest image file, which means only the latest image file is saved in the memory  32 , and the previous image file is overwritten. In this manner, only a small size of memory is need which saves the cost. 
     The control circuit  30  is also communicatively connected with a network  40 , preferably the internet. Therefore the control circuit  30  is able to transfer image data via the network, and receive information, such as control information for the user via the network. In a preferred embodiment of the present invention, the network interface  33  is connected with internet via TCP/IP protocol. 
     The control circuit comprises a device control  34  operatively linked to the image capture device  20  for selectively adjusting the capture interval and resolution of the image capture device through the network  40 . 
     The control circuit  30  also provides a web server function. When the network interface  33  is communicatively connected with the internet, the control circuit  30  runs a program which accepts HTTP requests from users such as web browsers, and provides HTTP serving responses along with data contents which is the image and video data. 
     In a preferred embodiment, the web server provided by the control circuit  30  acquires an IP address from the internet provider. Then the web server maps the path component of a URL (Uniform Resource Locator) to this IP address. When the user&#39;s web browser requests to visit this URL, the web server will then read the memory  32  of the control circuit  30  where the image data is stored, and send the data to the web browser. In this way the user&#39;s web browser is able to download the image data to display. It is worth mentioning, the image file is saved at the root direction of the HTTP web server. 
     In the preferred embodiment of the present invention, when the user&#39;s web browser is linked with the web server provided by the control circuit  30  via Internet, the web server then transfers the existing image file from the memory  32  to the web browser. Since the image file already exists, which is static content, the transferring is much faster than transfer dynamic content such as a video file. Also, the web server transfers the image file continuously and frequently without further request from the web browser, it also improves the transferring speed. Because the image file stored in the memory  32  is always refreshed continuously and frequently, the web browser will continuously and frequently receive the most updated image and display these file continuously with the video effect. Therefore, live image is able to be accessed by a web browser from internet. 
     Because every apparatus for live capture image of the present invention is working independently, each web server of the apparatus obtains an IP address and is able to be connected with internet individually. Therefore, a plurality of apparatus for live capture image of the present invention can be networked together to provide multiple channels images. 
     The web server of the control circuit  30  is also able to receive commands from the user&#39;s web browser for controlling. In the preferred embodiment, the control comprises using an integer to select channel, using a Boolean to enable/disable the image capture device  20 , and using a float to set the snapshot interval. 
     In an alternative embodiment, the control circuit  30  is connected with more than one image capture devices  20  to provide multiple channels of images. The channels can be selected by the user via network. The housing  10  comprises a plurality of units to receive the image capture devices  20  and the control circuit  30  individually. 
     The present invention also provides a web based system to broadcast multiple channels of images. Referring to  FIG. 3 , the system comprises a platform  50  to communicatively link with one or more live image providers through Internet which is one of the networks as mentioned above. The platform  50  collects live images from the live image providers via Internet, and presents these live images to observers via Internet. The live image provider captures live image, convert the image information into real time videos in predetermined format, and transfer the image data to the platform  50  via 
     Internet. In a preferred embodiment of the present invention, the platform  50  is a web based platform that the web browsers can access the platform  50  through Internet. 
     In a preferred embodiment of the system, the image capture device  20  of the live image provider takes snapshots frequently with a predetermined interval. The control circuit  30  of the live image converts the snapshots into image file, and uploads the image file constantly to the platform  50  via the internet. The image data is preferably in the format of still image file, such as JPEG file, PNG (Portable Network Graphic) file, GIF file, etc. These formats are standard formats which are supported by most web browsers, therefore the web user doesn&#39;t need to install any extra decoding program to view these images. 
     The snapshot interval of the image capture device  20  of the live image providers can be set by the user. The quality or resolution of each image file is also adjustable in responsive to the speed of Internet. In this way the user can control the data streaming. For example, when the transferring rate of the internet is high, and/or not many live image providers are uploading image files, the resolution of the image file may be higher for a better description of features. Also, the snapshot interval or the uploading interval could be shorter to provide smoother active effect of the live image. On the other hand, when more live image providers are connected with the platform  50  and the data transferring via the internet is heavier, a lower resolution, as well as a longer interval (lower frame rate) could be employed by the live image providers. 
     The live image provider may comprise more than one image capture device  20  to provide multiple channels of live images. These channels can be enabled or disabled by the user. The images of these channels can be transferred together or individually. 
     The memory  32  of the live image provider is used to store the image file. In a preferred embodiment, only the latest image file is saved, and the previous image file will be replaced by the most updated one. This will save a lot memory space. In an alternative embodiment, all image files are saved in the platform  50 . The live image provider always uploads the latest image file to the platform  50  for updating. 
     The platform  50  is first communicatively connected with the live image provider through the internet. Then the platform  50  receives the uploaded image files from the live image provider. The platform  50  is able to connect with one or more than one live image providers. Because the connection is through internet, the live image providers can be distributed in any location with the access of internet. The connection is also controllable. Only authorized live image providers are allowed to be connected with the platform  50 , which is also called registration of the live image providers. The platform  50  is also adapted to enable/disable particular live image providers and channels of the live image providers. The control also includes setting configures of each channels and live image provider such as snapshot interval and resolution, and security management. 
     Then the platform  50  presents the image file to show the live images provided by the live image providers, preferably in a web page. In the web page, the platform  50  display the most updated images received from each live image provider continuously. Since the images files are uploaded frequently and constantly with a relatively small interval, the displayed images are frequently refreshed which provides a real video image on the web page. When the user browses this web page, the user can watch those videos provided by those live image providers which are connected with the platform  50 . 
     Accordingly, the frame rate of the real time video like image is adjustable by the platform  50  and is selectively controlled in responsive to the capture interval of each of the live image providers. In particularly, the frame rate of the real time video like image is selectively adjusted in responsive to a refreshing time interval of the converted still image file at the platform  50  to obtain the latest converted still image files. For example, when the refreshing time interval of the converted still image file at the platform  50  is set at 3 seconds, the frame rate of the real time video like image is selectively adjusted at 1 frame per 3 seconds. It is worth mentioning that the capture interval of the live image provider can be set at any desired time interval. For example, when the frame rate of the real time video like image is set at 1 frame per 3 seconds while the capture interval of the live image provider is set at 1 frame per second, two still image frames, i.e. the second and third still image frames, from the live image provider will be useless and will not be shown on the platform  50 . Preferably, the frame rate of the real time video like image is set as the capture interval of the live image provider for optimum performance. Since the frame rate of the real time video like image is relatively low, such as 1 frame per second, in comparison with the frame rate of the video, such as 30 frames per second, the platform  50  can enhance the smoothness of the real time video like image in a real time manner. In addition, since the capacity of the still image is relative small, the still image can be instantly updated to the platform  50  to minimize the time delay of transferring. 
     The platform  50  also controls the access of the web page. Users or web users need to be identified to access selected web pages which display live images from selected live image providers. The authorized user is able to interact with the platform  50  and the live image providers for setting. The user can select/unselect channels and live image providers, set the resolution and snapshot interval. 
     The system of the present invention is using still image file to transfer the image data. First, still image file has common and standard format. The platform  50  doesn&#39;t need to do the encoding which will take a lot of system resource. Therefore the processing speed is much faster then dealing with video format such as MJPG, MP4, H.264, etc. The cost of manufacturing the system is also reduced. Also, the web user doesn&#39;t need to install particular decoding program to display the live image. The standard still image file can be displayed by regular web browsers, and not extra system resource is needed. As a result, the processing speed is much faster in the system of the present invention, and there is no compatibility problem for the web users. Second, since the size of the still image file is small compare with a video file, both the live image provider and the platform  50  can afford to save these file for record. This is very useful for many applications. Third, the system is highly controllable. The performance of the system is flexible to fulfill the requirement of any application. Because the capability of the Internet on physical layer is limited and uncontrollable by the user, the system of the present invention provides flexibility on the application layer. 
     Because of all the advantages, the system of the present invention is powerful and flexible in web based applications, especially when a large number of image channels are involved. For example, if the snapshot interval is 3 second, the size of each still image file is 70 K (kilo byte), then more than 100 different live images as the real time video images can be displayed together simultaneously. At the same time, the web browser doesn&#39;t need to install any extra program, the image resolution is acceptable without compression and losing frame. 
     It is worth mentioning that the live image provider is preferred to be the apparatus for providing live image as it is mentioned above. However, the live image provider can be CCTV or a mobile phone having a built-in camera such that the CCTV or a mobile phone can capture the still image and upload to the platform  50  to form the real time video like image thereon. In addition, the web browser is able to access the platform  50  to watch the real time video like image by using mobile phone, PDA, computer or other electronic devices which is able to communicatively link to the platform  50  through “WiFi”, Internet, or other communication network. 
     It is worth mentioning, using still image files also enable the platform  50  to edit and modify the live images to provide an add-on information for the live image files. Generally, for live videos, it is difficult to edit of modify the image on real time. But for still image files, for example PNG file, it is convenient to modify the image when display. Accordingly, the add-on information can be the comment or description of the image that adds onto the live image files. This provides the web server a great flexibility such as adding useful information on the live images. 
     Referring to  FIG. 4 , the present invention provides a method for transferring live images via internet comprising the following steps. 
     (1) Frequently capture live image information with a predetermined capture interval by one or more live image providers. 
     (2) Convert the live image information to a still image file in a web based viewable format. 
     (3) Continuously transfer the converted still image files to a platform via 
     Internet. 
     (4) Obtain the converted still image files at the platform to form a real time video like image at a predetermined frame rate by continuously overwriting the previous live image information with the latest live image information, so as to allow web browsers to watch the real time video like image without any proprietary software. 
     As shown in  FIG. 5 , the present invention further provides a method for transferring live images comprising the following steps. 
     (1) Capture live image information, such as a video, by one or more live image devices 20A. 
     (2) Continuously transfer the live image information to a platform 50A via communication network, such as Internet. 
     (3) Clone the live image information in a web based viewable format at the platform 50A. 
     (4) Broadcast the live image information as live streaming video over any web browser without any proprietary software, such that a user of the platform  50 A is able to concurrently view multiplicity of the live image information from the different live image devices  20 A. 
     According to the preferred embodiment, the user is able to view any one of the live image information anywhere through Internet. For example, the user is able to use personal computer with its operation system such as “Window®”, “Linux®”, or Mac®, to access one or more of the image capture devices  20 A in order to view the live image information. In addition, the user is able to use mobile phone, preferably supports Flash player” to view the live image information. 
     In other words, the user is requested to enter the platform  50 A in order to allow the user to view the live image information through the web browser by an Internet-enabled device such as personal computer, smart phone, tablet computer, and PDA. 
     As it is mentioned above, the image capture device  20 A is adapted to capture image information and converts the captured image information into electronic signals. Accordingly, the live image information is captured by the live image device  20 A in H.264 video raw streaming format. As shown in  FIG. 6 , each of the live image devices  20 A comprises a surveillance camera  21 A with built-in IP address for capturing the live image information and an encoder processor  22 A operatively linked to the surveillance camera  21 A for encoding the live image information in H.264 video raw streaming format. 
     According to the preferred embodiment, the platform  50 A is communicatively linking with the live image devices  20 A through Internet, wherein the platform  50 A can be a website or a server for the user to access through Internet. 
     In the step (3), when the live image information is cloned at the platform  50 A, the live image information is converted from the raw format into the web viewable format and an embed code  501 A is generated corresponding to the live image information at the same time. Preferably, the platform  50 A comprises a converter  51 A for converting the live image information from RTSP form to RTMP form through the platform  50 A, and a code generator  52 A linked to the converter  51 A for generating the embed code  501 A at the same time when the live image information is converted. 
     When the live image information is captured by the live image device  20 A, the live image information is transferred to the platform  50 A in RTSP (Real Time Streaming Protocol) form. Accordingly, the live image information is transferred to the platform  50 A through TCP/UDP before and after the live image information is converted at the platform  50 A. In other words, after the conversion, the live image information can be viewed by any web-based browser. In particular, the converter  51 A will transform the live image information into the RTMP (Real Time Messaging Protocol) form. It is worth mentioning that the live image information in different video formats can be transferred to the platform  50 A and can be converted into different video formats by the platform  50 A selected by the user. 
     At the same time, the embed code  501 A is also generated concurrently by the code generator  52 A. The embed code  501 A is a html source code being uniquely generated in response to the live image device  20 A and the platform  50 A. For example, when the live image information is captured by one live image device  20 A and is transferred to two different platforms  50 A, two different embed codes  501 A will be generated at the two platforms  50 A. Likewise, when two different live image information are captured by two different live image devices  20 A and are transferred to one platforms  50 A, two different embed codes  501 A will be generated at the platform  50 A with respect to the two different live image devices  20 A. Therefore, the embed code  501 A is a unique code corresponding to the live image device  20 A and the platform  50 A. 
     Once the embed code  501 A is generated, one or more users are enabled to use the embed code  501 A in order to broadcast the live image information over any website without any proprietary software. In particular, the embed code  501 A is a text code adapted to “copy-and-paste” to the website to link the live image information from the platform  50 A to the website, especially the personal website of the user, so as to live-stream the live image information from the live image device  20 A to the personal website. 
     Conventionally, only limited users can directly access and view the live image device  20  since the live image information is captured by the live image device  20 A in H.264 video raw streaming format. First, since different manufacturers manufacture different types of live image devices  20 A, the user must have a proper video media reader in order to view the live image information in such raw streaming format. Second, the live image device  20 A does not contain a powerful software and/or hardware that strong enough for hundreds of users to view the live image information at the same time. Therefore, the present invention provides the platform as a link to clone the live image information and to enable hundreds of users to view the live image information at the same time. 
     In addition, it is relatively complicated to link the live image information to the personal website in a conventional way. In other words, an additional software is a must to place the command of the live image information in order to link live image information to the personal website. On the other hand, the present invention simplifies the structure of the link that the user is able to “copy-and-paste” the embed code  501 A to his or her personal website, as shown in  FIG. 7 , wherein the live image information will be automatically shown on his or her personal website in live broadcasting manner. 
     According to the preferred embodiment, the platform  50 A is embodied as a software or a program adapted to be installed into a server owned by the user. The server can be linked to the live image device  20 A by cable or in a wireless manner such as Internet. Therefore, the live image information can be transferred from the live image device  20 A to the server and can be executed by the platform  50 A. 
     The present invention further comprises a control center  60 A communicatively linked to the platform  50 A preferably by Internet. In particular, the control center  60 A is a web-based station wirelessly linked to the platform  50 A. Accordingly, the control center  60 A provides an activation code to the platform  50 A for activating the live image device  20 A in order to transfer the live image information from the live image devices  20 A to the platforms  50 A in a live manner. In other words, without the activation code, the live image information will not be transferred from the live image device  20 A to the platform  50 A. 
     The control center  60 A comprises an initializing center  61 A for setting each of the live image devices  20 A, wherein the initializing center  61 A contains the activation code for identifying the corresponding live image device  20 A to the platform  50 A, and an input of a IP address of one of the live image devices  20 A for identifying the location thereof. 
     Before accessing the platform  50 A, the present invention preferably comprises the following installation steps. 
     (I) Install the live image device  20 A, i.e. for personal use, setting up the IP address of the live image device  20 A and RTSP port, wherein the IP address of the live image device  20 A can be set as “192.198.1.201” as an example, and the RTSP port can be set as 554 as an example. 
     (II) Install accessing software as the platform  50 A at the server or personal computer including inputting the activation code and the IP address of the live image device  20 A in order to access the live image device  20 A, wherein the software structures includes an executable binary file of the platform  50 A, a media player of the platform  50 A, and a live.html which is a webpage of checking video streaming and script code generated by the platform  50 A. The live.html file includes an embed source having the code of the designated live image device  20 A as the embed code  501 A. 
     (III) Login the control center  60 A to configure the live image device  20 A. 
     Accordingly, two or more of the live image devices  20 A can be linked together through the platform  50 A to establish a network, wherein each of the live image devices  20 A is adapted for being accessed through the platform  50 A by the user to view the corresponding live image information. In other words, the user is able to access the platform  50 A in order to select one or more live image devices  20 A to view the live image information. 
     It is worth mentioning that the user is able to install the platform  50 A into his or her server or personal computer that the user of the server or personal computer is able to obtain the activation code from the control center  60 A. Once the input of the activation code, the platform  50 A is automatically linked to the corresponding live image device  20 A to receive the live image information. 
     In the step (I), when the live image device  20 A is set up through a local area network (LAN), the server or personal computer will find the location of the live image device  20 A through a locator once the live image device  20 A is connected to a router through the local area network (LAN). Therefore, the information of the IP address, the port, device type, subnet mask, default gateway, and port forward corresponding to the live image device  20 A will be displayed on the platform  50 A. 
     Then, in the step (II), by downloading the software from the control center  60 A to the server or personal computer, the platform  50 A will be set up in the server or personal computer. The user is able to input the above information of the live image device  20 A through the set up process, such as inputting the activation code and the IP address of the live image device  20 A. 
     In the step (III), the user, i.e. the owner of the live image device  20 A, is able to login the control center  60 A in order to configure the live image device  20 A. 
     It is worth mentioning that the control center  60 A can track the live image information through the embed code  501 A. In particular, the control center  60 A is able to keep track which platform  50 A being used for broadcasting the live image information because the embed code  501 A is placed to the platform  50 A. In addition, the control center  60 A is able to obtain the numbers of viewers viewing the live image information from the platform  50 A. Therefore, the numbers of viewers will be shown in the control center  60 A to illustrate how many times the live image information from the live image device  20 A being viewed from the particular platform  50 A. In addition, the control center  60 A further provides a comment list placed below the live image information display for the viewers to leave any comment regarding the live image information. The control center  60 A will control the comments left by the viewers when any junk or impolite comment is left, the control center  60 A will remove such comment from the comment list and will prohibit any comment being left by the corresponding viewer. 
     As shown in  FIG. 8 , the control center  60 A further indicates the connection status of the live image device  20 A and/or the platform  50 A. A connection indicator  601 A is shown on the control center  60 A next to the display of the live image information that when the connection indicator  601 A shows when there is the connection between the live image device  20 A and the platform  50 A, the live image information will be shown on the display in live manner. When the connection indicator  601 A shows when there is no connection between the live image device  20 A and the platform  50 A, the control center  60 A will be notified to troubleshoot the problem of the live image device  20 A and/or the platform  50 A. 
     The control center  60 A provides a selection interface  62 A for allowing the user to select multiple live image devices  20 A to view more than one live image information. According to the preferred embodiment, each of the live image devices  20 A is selectively controlled between a private mode and a public mode, wherein at the private mode, the live image information from the respective live image device  20 A is adapted for being viewed by authorized user, and at the public mode, the live image information from any of the live image device  20 A is adapted for being view by any user of the control center  60 A. 
     The user, i.e. the owner of the live image device  20 A is able to set the live image device  20 A between the private mode and the public mode through the control center  60 A. For example, when the live image device  20 A is set to capture the image of the retail store, the user is able to set the live image device  20 A at the public mode, such that other users are able to view the live image of the retail store through the owner&#39;s website. When the live image device  20 A is set to capture the image of the store&#39;s entrance as the security camera, the user is able to set the live image device  20 A at the private mode. Therefore, only authorized users, such as security guard, can view the live image from the live image device  20 A. It is worth mentioning that an authorized code will be given by the control center  60 A to the authorized users upon the request from the owner of the live image device  20 A. 
     Accordingly, all the live image devices  20 A are shown in the selection interface  62 A. However, only the authorized user can access the live image devices  20 A at the private mode. In other words, the authorized user can access the live image devices  20 A in responsive to the authorized code from the control center  60 A. In order to set the live image device  20 A at the private mode, the user is able to select the corresponding live image device  20 A as an authorized manner such that other users cannot access the authorized live image device  20 A without any permission. Other users can access the authorized live image device  20 A by invitation of the authorized user. 
     In the step (III), the user is able to obtain the embed code  501 A from the control center  60 A, wherein the user is able to copy the embed code  501 A from the control center  60 A to his or her personal website for broadcasting the live image information. It is worth mentioning that the user is able to view the live image information at the control center  60 A as well to configure the live image device  20 A. In addition, having the embed code  501 A can be used as the source code for sharing the live image information. 
     It is worth mentioning that the embed code  501 A forms a shortcut for the user to broadcast the live image information. No other software or particular command is required for the user to set up his or her personal website to link with the live image device  20 A. Once the embed code  501 A is placed, by pasting the text code of the embed code  501 A, the live image information will be automatically displayed on the personal website. 
     For example, the live image device  20 A is set up at Venice Beach at California for capturing the live image of Venice beach walk. The control center  60 A will display the live image information of the live image device  20 A with the info and the embed code  501 A thereof. The user is able to “copy-and-paste” the embed code  501 A from the control center  60 A to the personal website as the source code such that the live image information of the live image device  20 A will be automatically displayed at the personal website as shown in  FIG. 7 . Therefore, after the embed code is copied-and-pasted at the personal website, the live image information will live-streaming from the live image device to the personal website. 
     In addition, all information of the live image device  20 A will be shown in the selection interface  62 A, which includes the ID of the live image device  20 A, the user ID of the live image device  20 A, the IP address of the live image device  20 A, the RTSP port of the live image device  20 A, the speed rate (Bitrate in/out) of the live image device  20 A, and the create date of the live image device  20 A. The number of current view and total view of the live image device  20 A will also be shown in the selection interface  62 A. 
     It is worth mentioning that the selection interface  62 A can be personalized by the user that only the information of the designated live image devices  20 A will be shown in the selection interface  62 A. Since thousands of live image devices  20 A will be installed at different locations, the user is able to select the designated live image devices  20 A in the selection interface  62 A in order to view the live image information. The user can always add or delete the live image devices  20 A in the selection interface  62 A. 
     According to the preferred embodiment, the control center  60 A further provides multi-functions including PTZ (Pan-Tilt-Zoom) control of the live image device  20 A, preset point recall, and volume control, in order to control the live image device  20 A with audio steaming. Thus, the live image device  20 A can be controlled with snapshot ability, snapshot image quality, record the live image information, and configure the recorded file (query, play, delete, and download) through the control center  60 A. 
     The user is able to setup only one live image device  20 A, i.e. the single live image device version, using it in purely LAN. Accordingly, the accessing software can be firstly installed inputting the activation code and the information of the live image device  20 A, such as the IP address of the live image device  20 A. Then, the platform  50 A will automatically convert the live image information in raw H.264 from the live image device  20 A into RTMP steaming. After the installation is finished, the user is able to open live.html and view the streaming video as the live image information from the corresponding live image device  20 A. It is worth mentioning that the live.html page will automatically generate live image information streaming embedded scripts (html source code). Source code, i.e. the embed code  501 A, can copy-paste to any webpage on any website, so as to provide flash streaming video over Internet. 
     For multiple live image device version, the accessing software can be firstly installed inputting the activation key and the information of the live image devices  20 A, such as the IP addresses of the live image devices  20 A. Then, the user must login to the control center  60 A in order to register thereof. Therefore, the platform  50 A will automatically convert the live image information in raw H.264 from the live image device  20 A into RTMP steaming. Accordingly, a maximum number of the live image information from different live image devices  20 A will be set by the control center  60 A in order to allow the user to be concurrently viewed from the live image devices  20 A. After the installation is finished, the user is able to view the streaming video as the live image information from the corresponding live image device  20 A over any browser through Internet. 
     According to the preferred embodiment, the control center  60 A further comprises a managing center  64 A managing the live image devices  20 A in order to remotely control an operation of each of the live image devices  20 A in an authorized manner. As it is mentioned above, the live image device  20 A can be controlled its PTZ (Pan-Tilt-Zoom) control, preset point recall, and volume control through the managing center  64 A. In addition, through the managing center  64 A, the user can add new live image device  20 A, delete current live image device  20 A, enable/disable the currently live image device  20 A, share the live image device  20 A (set to share or set to privilege), check and verify software version number, check and verify the maximum connection of the live image device  20 A, check current live image device  20 A connected, check total live image device  20 A connected, check live image device  20 A bit rate, view live image streaming video, automatically check embedded source code generated by the platform  50 A to be able to copy-paste to any page on any website, and check log of the platform  50 A. 
     Accordingly, the platform  50 A of the preferred embodiment has the following bandwidth consume properties. The bandwidth equals to the sum of inbound bitrate and outbound bitrate. The inbound bitrate is a single channel that the platform  50 A obtains raw RTSP streaming from the live image device  20 A. The outbound bitrate is multiple channel that each user takes one channel. Therefore, the bandwidth consumption is related with the users viewing live information from the live image device  20 A. In addition, the platform  50 A will use one channel to obtain live image information such that one single channel read video contents and multiple users can view the same live image device  20 A. 
     The platform  50 A default set is not connected to any live image device  20 A until the user requests to access thereof in order to view the live image information for energy saving. When on user on the website, the live image device  20 A will be automatically switched off for energy saving. In other words, the control center  60 A will automatically switch off one of the live image devices  20 A when the corresponding live streaming video therefrom is not be viewed. It is worth mentioning that using RTMP port (default is 1935), multiple live image device version will be open communication port (default is 7000). 
     One skilled in the art will understand that the embodiment of the present invention as shown in the drawings and described above is exemplary only and not intended to be limiting. 
     It will thus be seen that the objects of the present invention have been fully and effectively accomplished. It embodiments have been shown and described for the purposes of illustrating the functional and structural principles of the present invention and is subject to change without departure from such principles. Therefore, this invention includes all modifications encompassed within the spirit and scope of the following claims.