WO1999030500A1 - Interactive cable television system with frame server - Google Patents

Abstract

In an interactive cable system having a plurality of assignable interactive controllers which communicate with subscribers through an information service distribution network, a frame server is provided for interfacing with a plurality of subscribers. A system manager assigns either the frame server or one of the plurality of interactive controllers to subscribers requesting interactive service. The frame server preferably delivers interactive pages which need only be transmitted intermittently, such as still frame images.

Description

INTERACTIVE CABLE TELEVISION SYSTEM WITH FRAME SERVER

Field of Invention This invention relates to cable television systems, particularly those providing pπvate channels on demand to users tor interactive- type services.

Background Art

Bandwidth problems have long restπcted the ability ol cable television systems to provide pπvate lnlormation services to subscπbers. Such intormauon services may include Internet access, video-on-demand, games, catalogs, etc. Private services may also include allowing the user to select trom among hundreds of less popular programming that is thus made available only on a demand basis. One solution to the limits on system bandwidth has been to assign a portion ol cable system bandwidth to conventional or popular channels that are universally broadcast to all subscribers. The remaining available channels are then available tor assignment to requesting subscπbers on a demand basis.

One such system tor providing interactive services on a demand basis is described in U.S. Patent No 5.550.578 The lull disclosure of this reterence is hereby incorporated by reterence herein. Basically the cable service distπbution network divides the subscriber pool into vaπous service areas, each served by a ditterent trunk. A rst group ot channels broadcast to all service areas may provide conventional channels on channels 2 to 73 tor example A second group ot channels, 74 to 79, tor example, may be reserved for pπvate information services. While the information on channels 2 to 73 is the same in each service area, the intormauon on channels 74 to 79 is different in each service area. Ot these channels, those that are in use are individually assigned to requesting subscπbers. Subscπbers receiving analog signals will use a lull channel, those receiving digital signals will share the assigned channel with other subscπbers on a packet addressed or time shared basis. A subscriber in one service area may be interacting on channel 74 at the same time a different subscriber in a different service area was also assigned to channel 74. The headend is equipped with the necessary processing, switching or splitting and combining systems tor setting up these pπvate channels on demand. Once assigned a channel tor interactive services, the subscπber can request trom any ot a number ot interactive services. Ditterent interactive services may be accessed by the user requesting a ditterent channel. For example, channels 80 to 300 can be virtual channels each ot which accesses a ditterent interactive service. As the subscπber continues to change channels among the interactive alternatives, the program being watched will change but the subscπber will remain tuned to the assigned channel tor receiving interactive services. The information services can thus be provided to a subscπber over virtual channels in which the channel number changes tor ditterent interactive intormauon services, even though the vaπous intormauon services may be provided over a tixed trequency input to the set top The control data trom the subscriber^'s set top can cause the back end to supply a ditterent information service as the subscriber appears to be changing the channel.

In the system ot U.S. Patent No 5.550.578. the headend includes a finite number ot interactive controllers (or processors) tor assignment to subscπbers requesting interactive service The interactive controllers are otten dedicated to a particular type ot interactive service whether it be Internet access, games, catalog shopping, movies or other service Thus lor interactive service as a whole and particularly tor given types ot interactive services the available resources at the headend in the torm ot interactive controllers is limited. It is expensive and theretore undesirable to provide a lull complement ot interactive controllers tor each given type ot interactive service tor each service area.

Summary of the Invention

The present invention is directed to an interactive cable system in which a trame server is included in the headend along with a plurality ot assignable interactive controllers. The trame server ot an embodiment ot the invention interlaces with a plurality ol home interlace controllers. Each home interlace controller is associated with a subscriber television and a subscπber selection device that permits subscπber interaction. The frame server generates display images to be supplied to the subscriber television associated with the assigned home interlace controller in a digital television signal over the cable system's information service distπbution network. The display images trom the trame server are preferably limited to interactive pages as detined herein. The subscπber selection device ot a home interlace controller assigned to the trame server can communicate with the trame server through a transmitter in the home interface controller and over a data communication link. The data communication link is typically either a trequency band on the cable distribution network or the telephone lines.

The plurality of interactive controllers also at the headend each receive data communications trom an assigned home interlace controller. The interactive controller generates information signals to be supplied over television signals through the information service distribution network to the subscπber television ol the assigned home intertace controller. A system manager in the headend is in data communication with the home interface controllers so that it can assign the frame server or one of the interactive controllers to a home interface controller requesting interactive service.

The trame server advantageously accommodates a large number ol subscπbers requesting interactive service so that the overall demand lor interactive controllers is reduced. Such a system can be cost etlectively built with fewer interactive controller cards and modules than would otherwise be needed to satisty subscriber demand lor interactive services. Other objects and advantages ot the present invention will become apparent duπng the following descπption ot the presently prelerred embodiments ol the present invention taken in coniunction with the drawings.

Brief Description of the Drawings Fig. 1 is a block diagram ol a headend tor an embodiment ot the present invention.

Fig. 2 is a block diagram of a back end for use in the headend ol Fig. 1. Fig. 3 is a block diagram ol a Iront end tor use in the headend ot Fig. 1 with an exploded view ol an analog user service module.

Fig. 4 is a block diagram ol a Iront end tor use in the headend ol Fig. 1 with an exploded view of a digital user service module.

Fig. 5 is a block diagram ol a trame server tor use in the headend ol Fig. 1. Fig. 6 is a block diagram ol a switching output RF hub tor use with the headend of Fig. 1. Fig. 7 is a block diagram ol a home intertace controller lor use in connection with the headend ot Fig. 1.

Figs. 8A-8F illustrate examples ol subscπber television screen displays during an interactive session. Fig. 9 illustrates a system diagram ot a system manager tor use in the headend of

Fig. 1.

Fig. 10 is a flow diagram tor a call set-up and tear down procedure lor use by the system manager of Fig. 9.

Fig. 1 1 illustrates the trequency spectrum ol the various signals used by a cable television system incorporating the headend of Fig. 1.

Fig. 12 is a high-level diagram ol a home intertace controller in communication with the back end.

Fig. 13 is a high-level diagram illustrating a cable return system

Detailed Description of Specific Embodiments

For the purposes ot the description herein and the claims that follow it, unless the context otherwise requires, the terms "cable television environment'^' and "cable television system'^' include all integrated systems tor delivery ot any information service to subscribers tor use in connection with their televisions. These include conventional cable television systems utilizing coaxial cable lor distπbution pπmaπly ot broadcast and paid television programming, cable television s\ stems using tiber optics and mixed fiber optic-coaxial cable, as well as other means tor distribution of intormation services to subscribers. Similarly, unless the context otherwise requires, the term "information service" includes any service capable of being furnished to a television viewer having an intertace permitting (but not necessarily requiring) interaction with a facility ot the cable provider, including but not limited to an interactive information service, video on demand, Internet access, local oπgination service, community event service, regular broadcast service, etc. "Television communication^" means providing an intormauon service via a television information signal. A "television intormauon signal'^' is any signal that may be utilized by a television lor video display, regardless ot the torm, including a standard NTSC-modulated rt earner, an MPEG-compressed digital data stream, or any other format. ^"Interactive television service^" means an intormauon service that utilizes an intertace atfording two-way communication with a facility of the cable provider When a home intertace controller is said to be in an "interactive mode," it means that the interactive television intormauon system is providing an information service to the home intertace controller "Interactive pages^" are detined herein to include still video trame images or a multimedia short scπpt tor interpretation by a local process such as a typical page ot HTML data as practiced by conventional web browsers. Thus the interactive page may show cursor movement or flashing or revolving images under local process control. An interactive page is typically sent intermittently trom the trame server. It does not require the trame server to continually send video information multiple times a second.

A cable television system comprises a headend and distribution plant. The cable distribution plant includes a cable distribution network having bπdger amplifiers, leeders. feeder amplifiers, and cable drops serving homes.

Relerπng now to Fig. 1. a headend is illustrated tor providing interactive services. The headend includes back end 1 1. tront end 12. and switching output RF hub 13. Data communication trom subscπbers is delivered thru a return data path to the back end 1 1 ot the headend. One alternative return path is through telephone lines to telephone return path processing block 101 Another alternative return path is through a reserved trequency band throughout the cable network. For example, the 5-40 MHZ band may be reserved lor data communication trom subscπbers to the headend. Cable return path processing block 1 2 is in communication with such signals provided over a cable return path. Telephone return path processing 101 and cable return path processing 102 are connected through return path switches 103 with user service cards 202 and trame server 206. The user service cards 202 each contain a processor that acts as an interactive controller which is individually assignable to a requesting subscπber on a demand basis. The interactive controller receives the data trom its assigned subscriber and produces the information to be delivered to the subscπber in a television signal. The frame server 206 is one or more processors which interface with a plurality ot subscπbers. Processes running on the trame server 206 may be individually assigned to subscπbers or may handle interactions with a plurality of requesting subscribers. Each interactive process on the trame server 206 responds to data trom a subscriber and produces the intormauon to be delivered to the subscriber in the torm ot a television signal.

The back end 1 1 further provides intormation sources to the tront end 12. A network intertace 104 is in communication with an Internet service provider. Back end switches 105 are in communication with the network intertace 104 and web and application server CPU's 106 as well as system management CPUs 1 13 Communications are completed with the tront end 12 through back end switches 105 via distribution switches 201. Because the user service cards in a preferred embodiment are diskless and lack operating system software necessary tor bootup, server 106 may also provide booting-up tor the interactive controllers Also, server 106 provides a web proxy server function so that intormation downloaded trom a remote server on the Internet is quickly cached on server 106.

Distπbution switches 201 provide communication signals and control signals to the user service cards 202, the trame server 206. MPEG to video decoder cards 208 and MPEG2 pass thru 209. MPEG and MPEG2 digital encoding schemes are referred to herein by example only. Those ol ordinary skill in the art should readily recognize that the present invention may be practiced with other currently available and later developed schemes tor dehveπng video intormation through digital signals The user service cards may be dedicated to any ot a vaπety of interactive services. For example, there may be Internet service cards lor running web browser processes and other video game player cards tor running video game processes. The MPEG-to-video decoder cards 208 and the MPEG2 pass thru 209 are tor providing video to subscπbers on demand

NTSC/PAL TV modulator cards 203 provide analog television signals trom the outputs ot the user service cards 202. The television signals are in the torm ot NTSC or PAL IF (intermediate trequency) signals. NTSC/PAL TV modulator cards 210 are also provided tor providing video on demand on analog signals. The analog signals trom the user card chassis NTSC/PAL TV modulators 203 and the video on demand NTSC/PAL TV modulators 210 are provided to initial RF processing 301 and 303. respectively, in the switching output RF hub 13. The initial RF processing includes upconverting the NTSC/PAL IF earner signals onto a frequency determined by the channel trequency assigned to the subscπber destination. Channel assignment and control ot any adjustable upconverters is handled by system management CPUs 1 13 which are in communication with the switching output RF hub 13 through communication lines not shown. In a presently preferred embodiment, a user service card 202. an NTSC/PAL modulator 203 and an upconverter may all be packaged in a single module. The module as a whole would be assigned to a requesting subscnber. MPEG2 real time encoders 204 provide digital television signals trom the outputs of the user service cards 202. The frame server 206 includes an MPEG encoder to provide digital television signals as well. Videos may be stored in MPEG format and may therefor use pass thru 209 to directly provide digital television signals. The digital signals are combined into a composite 64QAM (quadrature amplitude modulation) signal betore going to initial RF processing. The digital signals are multiplexed so that many different signals may be earned on a single analog earner. Multiplexer and 64QAM encoder 205 receives signals from the user chassis' MPEG2 real time encoders 204 Multiplexer and 64QAM encoder 207 receives signals trom the trame server 206. 64QAM encoder 21 1 handles the video signals trom the video on demand chassis. Within switching output RF hub 13. initial RF processing 301 , 302. 303 is performed in which there is one RF module per simultaneous user The output of RF processing 3 1.302,303 is switched tor delivery to the service area ot each respective subscnber destination and all signals going to a particular service area are combined via switcher- combiner 304 The combined signals tor each service area pass through a tinal RF processing 305

An embodiment ot back end 1 1 is shown in more detail in Fig. 2. Cable return path processing 102 is provided by a bank of RF modems 102b. Splitters 102a extract cable signals lor processing by the RF modems 102b Telephone return path processing 101 is provided through the public service telephone network 101a to an integrated channel bank and modem 101b. Network intertace 104 is provided by router tirewall 105b and CSU/DSU (customer service unit/data service unit) 105a. Router tirewall 105b is in communication with Ethernet switch 108 Also shown in Fig. 2 are web proxy and application server 107, system manager 108. network manager 109 and commerce manager 1 10 in communication with Ethernet switch 108. System manager 108 provides lor the allocation ol resources to permit interactive services with a user, as well as procedures for call set-up and tear down. Commerce manager 1 10 manages realtime transactions and converts billing to a batch format tor handling by legacy systems. Also shown in Fig. 2 are operations console 1 1 1 and boot server 112 in communication with Ethernet switch 108

An embodiment ot tront end 12 is shown in Figs. 3 and 4. The user service cards are prelerably each housed in a single user service module 212. Ethernet switches 201 are connected to the user service modules 212. The composition ot the user service modules depend on whether they are to be used for analog or digital video signal processing. Arrangement ot a pret erred analog user service control module 212a is illustrated in Fig. 3. A return path intertace 202e receives data signals trom an assigned subscnber. A LAN interface 202f enables data communications between the user service card and the headend network accessed through the distnbution data switches 201. This gives the user service card 202a access to various intormation sources and to the system management CPUs 1 13. The interactive controller is found preterably in a PC card 202a which is a personal computer on a single board. The NTSC/PAL TV modulator 203 includes a VGA to NTSC/PAL converter 203a. a scrambler 203b and an RF modulator 203c . The scrambler 203b can be a complete conventional scrambler providing in addition to a scrambled television signal output, a signal authorization tor data transmission to the assigned subscnber to allow descrambhng at the subscriber's set top. Alternatively and prelerably. the scrambler 203b is a simplified scrambling unit that performs sync suppression to scramble the signal and is provided with a conditional access code (tag) tor insertion into the scrambled signal. In such a system, a separate scrambler including an encrypter. an encoder and an access controller is provided in the tront end 11 tor each channel trequency The access controller sends the signal authonzation to each subscriber assigned to the channel trequency in any ot the service areas. The signal authonzation will typically include a key for decrypting the conditional access code. The encrypter encrypts the conditional access code. The encoder places the conditional access code into a scrambled reterence video signal. An extractor in the separate scrambler tor the given channel trequency removes the conditional access code from the reterence and communicates it to each interactive control module active at the given channel trequency. The interactive control module provides a path lor the conditional access code into the video scrambler 203b where it is inserted into the scrambled signal. The conditional access code may be inserted into the vertical blanking interval (VBI) or the audio subcarner depending upon the desired system design. The RF modulator 203c may include an IF signal that is modulated by the scrambled television signal to produce tor example a 45MHz IF carrier lor the scrambled television signal It has also been lound convenient to include the initial RF processing 301 in the analog user service control module 212a This involves including an RF upconverter tor receiving the modulated IF carrier and raising the carrier to a frequency determined by the assigned channel trequency

Fig. 4 illustrates a digital user service control module 212b. It can be seen that the digital user service control module 212b is similar to the analog user service control module 212a as for the data input interlaces and the use ot a PC card to act as the interactive controller. In the digital control module 212b. the intormation signal from the PC card 202a is provided to a VGA to YUV converter 204a. The digital YUV output is encoded. The presently preferred encoder is an MPEG2 video encoder 204b and an associated MPEG2 audio encoder 204c The encoded digital television signal is input to a tirst stage ot an MPEG2 multiplexer 204d. To the extent the cable system is also used to handle pπnt requests trom subscribers, pnnter output can be sent trom the PC card 202a to the tirst stage ot the MPEG2 multiplexer. The printer output would ultimately be directed through the cable system to a settop and a pnnter connected to the settop. All outputs trom the tirst stage MPEG2 multiplexers 204d are passed to the multiplexer and 64QAM encoder 205. This includes Ethernet Switch 205a. MPEG2 Re-Multiplexer 205b and 64QAM encoder 205c The 64QAM encoder 205c produces a 45MHz IF signal which can then be upconverted in initial RF processsing 301.

In accordance with an embodiment of the present invention, a trame server 206 is advantageously included in the headend. The trame server 206 is one or more computers for running numerous processes, each interacting with one or more assigned subscribers. Typically, it is expected that the trame server would be used for providing pπmanly interactive pages. The frame server will typically provide initial service to a requesting subscnber, tor example, for logging on and establishing initial service. The trame server can also be elfectively used to deliver email messages, informational messages such as sports scores, transit schedules, weather, stock prices and other still trame oriented content. Other services can include Internet web browsing, catalog shopping, and electronic program guides. The inclusion ol a trame server significantly reduces user demand lor user service cards and thus holds down the overall cost ot headend equipment. Rather than requiπng a user service card for every subscnber that activates the interactive mode, the trame server allows many subscribers to receive interactive service without connection to a user service card. Indeed, the trame server is intended to provide an application source that is always available to respond to user interactions. Thus the system does not block but can always respond to an arbitranly larger number ot users albeit one trame at a time.

A subscnber interacts with a particular application within the frame server environment. The resulting outputs trom the application are captured one display trame at a time and converted to the MPEG2 or other suitable tormat. Alter conversion, the trame is transmitted to the user tor decoding and display on the user's television set. The trame server uses one digital channel on a cable television or other broadband system. All subscribers accessing the trame server connect to the common channel. A trame of video representing the output ot the software application with which the subscriber is interacting is uniquely addressed to that subscπber and transmitted over the common channel, much as all packet switched networks operate. Only the digital settop terminal to which the trame ot video is addressed will decode the trame. It is expected that a subscnber interacting with a trame server application will receive requested interactive pages in less than two seconds trom the subscnbcr's request

Reterπng now to Fig. 5. the trame server 206 will be described in greater detail. The trame server system will typically operate as a collection of individual software processes that run on a single computer tor small system use The trame server can be scaled to run on a networked cluster of computers acting in concert. The frame server 206 includes a plurality ot information servers. These may include a web server 206b, a mail server 206c. a news server 206d and a message server 206e. Each intormation server provides its own particular class ol information. Locally generated messages are created by the message page generator 2061 which provides those pages to the message server 206e. A cluster ot message servers assist in the generation ot pages ot information and cover vaπous message types including in the presently preferred embodiment a customer service message server 2()6g. a help and error message server 206g' and a third-party message server 2()6g". The third-party message server encompasses such content as local advertiser messages. Regardless ot server source, the message pages (video frames) are presented by the various respective servers to the user web browser 206h. All messages are created using HTML protocol so that regardless of source, the intormation is rendered via a web browser process 206h. The subscriber interacts with a web browser process via a return path processor 2()6q and request scheduler 206r. The return path processor receives user keyboard and pointer (mouse) commands from subscribers via the return path switch 103. The received user commands are processed by the return path processor 206q and passed to the request scheduler 206r lor routing to the web browser process 206h handling a given user. The web browser establishes a state machine that tracks the user's inputs and generates requests to the appropnate server source.

Each active web browser process 206h renders an image in RAM trom HTML source received from a particular server. The rendered output is then passed to an RGB to YUV display driver 206] which converts the program generated display information from the standard RGB tormat to YUV which is the input format used by MPEG2 compression systems. This YUV rendered display trom is stored in a user virtual display memory 206k. A multiplexer, reterred to herein as a user encoder queue manager 206m, sequences the multiple user display pages through a FIFO to queue up lor the MPEG2 I- trame encoder 206n lor MPEG compression. The compressed signals are eventually transmitted to the respective subscπber via MPEG trame addressing 206p which provides addressing and system intormation appropriate to the digital settop in use by the system. The resulting data stream, including various user display frames, is routed into the switching output RF hub tor distribution to the requesting subscribers.

An embodiment ol switching output RF hub 13 is shown in Fig. 6. Initial RF processing is performed by RF up-converters 301. converting 45 MHZ input to an output in the range of 150 to 300 MHZ. The upconverters are preferably capable ot modulating a earner that is tunable under control of the system management CPUs 1 13, so that any given upconverter may be configured to best handle demands placed on the system. RF switch and combiner network 304 provides the upconverted signals to final RF processing 305, which in Fig. 6 are indicated by block channel converters 305a and amplifiers 306. There is one block channel converter 305a tor each service area. The interactive signals lor delivery to a service area are combined with broadcast channels that are identically transmitted to all service areas. Fig. 6 illustrates this tor one ot the service areas where combiner 307 is shown. An optical transmitter 308 is used for sending the combined signals out over optical tiber.

Each subscriber ot the system is equipped with a home intertace controller 401 through which all interaction is conducted with the headend. Preferably, the home intertace controller both receives the television signals trom the cable and conducts data communication. However, the data communications could be handled by a separate box connected to a phone line, it desired. A presently preterred home intertace controller 401 is shown in Fig. 7. A cable carrying the television signals trom the subscriber's service area is connected to a two-way splitter 402 which may also be connected to a cable set-top 403 provided by a third party. A diplex filter and combiner 404 provide a first trequency path to splitter 405 and a second trequency path to FSK (frequency shift- key) radio 415, where the tirst trequency path occupies a higher spectral region than the second trequency path. The first trequency path provides a downstream path tor signals going trom tront end 12 to the user ot the home intertace controller whereas the second trequency path provides an upstream path tor signals going trom the user to tront end 12. An alternate upstream path may be provided through telephone lines via a telephone intertace 413.

Splitter 405 provides a signal path to low pass filter 406 and an impaiiment removal circuit 417. The outputs ot the low pass filter 406 and the impairment removal circuit 417 are re-combined at combiner 407. then amplified by amphlier 408. Switch 409 allows the user ot the home intertace controller 401 to switch between the signal output of amplifier 408 and the output ot the third party set-top 403 (it present) Switch 409 may also be under control ol home box CPU 410

Home box CPU 410 provides control and communication signals to impairment removal circuit 417, FSK upstream radio 415, telephone intertace 413, senal port 414 and lnlrared transmitter 412. FSK upstream radio 415 is a modulator lor providing a data communication link through a low trequency band on the cable between the home interface controller 401 and front end 12. Collectively, the upstream radio 415 and downstream radio 416 constitute the transmitter and receiver, respectively, ol a data transceiver. In addition to or instead ot the FSK upstream radio 415, telephone intertace 413 can be used to provide communication over ordinary telephone lines to the tront end 12. Intrared transmitter 412 may be used to communicate with the cable set-top 403 or the television. For example, when interactive mode is requested, the intrared transmitter can transmit the assigned trequency to the set-top or television tuning the appropπate appliance to receive the interactive television display. The frequency is learned by the CPU 410 through the downstream radio in communications trom the headend. Intrared receiver 41 1 receives commands trom a subscriber selection device. The subscriber selection device may be a typical television remote control or may include a keyboard, a mouse or other input device. The subscπber will have a channel selection input available for selecting a program on at least one of the available selection devices. A serial port 414 may be advantageously included on the home intertace controller to provide communication with a printer tor hard copy printouts. The serial port enables the subscriber to connect a printer to the home intertace controller. When a subscπber is using the interactive system to browse the Internet, read email, review advertisements or other still trame viewing, a pπnt command can be used to obtain a pπntout ot information. When the pnnt command is received by an assigned interactive controller at the headend such as in digital control module 212b. the output to the subscπber can be changed to a printer output which the home intertace controller receives and passes along through the serial port to the attached pnnter.

It is contemplated that households having pnnters. generally have them attached to their home computer Such persons may be unwilling to purchase an additional pnnter for their interactive television system or to move their pnnter trom the computer to the television. The interactive system described herein may be used to create a virtual local area network An additional home intertace controller may be installed in the home tor connection to the pnnter. The television cable into the home may be connected to this home intertace controller in addition to connection with the home interface controller ol the television. A subscriber operating in interactive mode and viewing a television screen may activate a print command by clicking a mouse with a cursor on the screen over a pπnt icon, by simply keying in a pnnt command or other input method. The application at the headend communicating with the subscπber will ask the subscπber to which home intertace controller should the print output be sent. The destination tor print output can be preentered as a default, set up early in an interactive session or entered when printing is desired When the pπnt command and destination are received at the headend, the printer output trom the application can be addressed to the destination home intertace controller instead ot the requesting home interlace controller. When printing is complete, the application can return to interacting with its assigned requesting home interface controller. In accordance with this method of operation, the destination home intertace controller can be anywhere on the cable distribution network. Thus a user can cause a pπnt out at an otfice pnnter. a relative's pnnter or indeed any pnnter the user can identity. For the user at home, printing through a printer at home it may seem that the print command is causing a transfer ot the screen being viewed on television directly to the printer in another room. In reality, the pnnt command will travel up to the headend causing the headend to deliver the print output down through the cable to the designated home intertace controller with an attached pnnter. The home intertace controller will need to always be listening to a data communication link or to the trame server common channel so as to recognize and receive intormation addressed to itself.

When a user of the home interlace controller requests an interactive service trom head end 12, such as Internet service or a video game, an appropriate trame server application or user service module is placed in use tor providing the service to the user. The user selects the desired service by using the subscriber selection device in conjunction with the home intertace controller. Examples ot screen displays available to the user tor selection ot a service are illustrated in Figs 8A-8F. Fig 8A shows a beginning display, in which tront end 12 requests appropriate information from the user, including a PIN code number. In this way. tor example, children may be blocked trom requesting unsuitable video content. Once the back end 1 1 identities the user (this will be discussed in more detail later), various options are available, as shown in Fig 8B. Fig. 8C shows a screen in which the ''news" option of Fig. 8B has been chosen. In Fig. 8C, once the user has decided to choose a news program, the user may decide to choose CNN or MSNBC. Fig. 8D shows the screen when the user has selected the CNN option of Fig. 8C. Fig. 8E is similar to Fig. 8B, except that this screen appears when the "Junior" button and appropriate PIN code is entered in Fig. 8A. Fig. 8E shows the screen that results when the "gaMes^" button in Fig. 8E is entered. It should be noted that the interaction here is via an Internet-type browser, which permits not merely surling the Internet, but actually selecting different intormation services using hyperlinks Fig. 9 illustrates a system diagram tor system manager 108, indicating the two lunctions of ( 1 ) call set-up and tear down and (2) resource allocation with the interactive TV system of Fig. 1. Call set-up is the process of causing the assignment ot a television information signal path to the home intertace controller lor interactive service, and resource allocation is the process ot assigning appropnate user service cards and virtual circuits within the switching system in the back end.

Call set-up is initiated by a small program in the home intertace controller which keeps track of the channel the user is watching. The channels are broken into bands where, for instance, channels 2 through 73 are assigned regular TV programming both off-air TV channels as well as cable channels such as MTV. HBO, CNN, etc. The band above this broadcast band uses channels 74 to 79, for instance, tor interactive services where a user is assigned one of these channels only during the duration of that user's interaction with the interactive TV system (i.e. - while looking up a restaurant in the entertainment guide, or while watching a movie, etc.). A user may tune trom a broadcast channel (e.g. - ch. 37 CNN) to an interactive service virtual channel, at which time the user will be provided with the screen displays of the type shown, tor example, in Figs. 8A through 8F. When the user selects interactive service, the small program in the home intertace controller sends a signal to the system manager at the back end to initiate call set-up. The system manager in back end 1 1 begins the call set-up process through a system manager subsystem called the call setup server (CSS) 80. The CSS 80 tinds a tree interactive element or selection element corresponding to the virtual channel number the user is trying to tune to. As an example, assume the user is interested in movie previews which are viewed through interacting with a user service card and a program run on service "A" application process 81 1. The CSS 80 will call a video path manager subroutine to check for an available television information channel within the band ot television intormation signals allocated to provide interactive service to the neighborhood of the requesting user. The newly assigned television information signal of the requesting user and the user's network address is passed to a service allocation server (S AS) 81 associated with the application process.

Assuming a non-blocked call, the system management function has now passed trom the CSS 80 sub-system to the SAS 81 (for this example). The CSS 80 is now out ot the loop. The SAS 81 checks tor a tree resource, i.e.. a processor tor running a service application process. If one is available, control is passed to it along with the assigned television intormation signal and address of the calling user. The processor, in this example, is a user service PC card 202a. The service application process run by the PC card 202a sends a request to the application support server 87 tor subscnber information to authenticate the user id tor the neighborhood from which the signal is onginating. The service application process also requests subscπber intormation trom the application support server 87 customer database to check tor paid-up service and/or access to service permission (e.g. - used to block children trom viewing R rated movie previews, for one example). Upon success, the service application process directs the conditional access controller (CAC) 86 to send a descramble key code to the user's set-top converter to allow it to descramble the video signal that the service application process will be using. The service application process also communicates directly with the in-home operations process (IHOP) 85 running in the home intertace controller CPU 410, lnlorming the program ot the assigned television intormation signal. A separate processor in the set- top receives the descrambhng authorization keys and translates them.

The set-top HOP 85. upon receiving the assigned channel, tunes the cable TV set-top to the assigned channel The user will see the output ot the SAP 81 1 and can begin using the remote control to manipulate the program running on the SAP 81 1. The in-home operation process 85 transmits appropπate remote control commands addressed to the processor/process assigned to it. When the user tunes to a broadcast TV channel, the call take down process is initiated by the set-top system manager extension signaling the 81 1 that the user has tuned away, and. alter a time-out period (tor instance, live minutes), the 81 1 signals the call set-up server 80 to release the interactive virtual channel previously assigned. The virtual channel is logged back into the tree channels list by the CSS 80. At the same time, the SAP 81 1 signals the SAS 81 that it is now a tree resource and the SAS places the user service card that had provided the application process on its tree card list.

The example above is the same for other kinds ot user service cards tor interactive multimedia, such as video game player cards, and MPEG-to- video decoder cards 208. A user service card can be used for a tront end application such as movie previewing and purchasing. When the user picks a movie using a user service card, the user service card will then pass control ol the user to a control program that manages movie playback and decompression (MPEG2 to NTSC) When the movie is over, the movie playback control program lollows the same steps ot call take down as the user service card did The above system management scheme can accommodate any number ot diverse services in a fully distnbuted manner such that there are no bottlenecks in the system This affords optimal pertormance in response to user requests. By distributing the processing of communications with home intertace controllers throughout system management, a greater amount of processing can be conducted in less time with less expensive processing units.

System management may include separate service allocation servers 81 or 82 for each ol the video on demand system, the digital user service cards and the analog user service cards. Moreover, there may be additional service allocation servers further dividing the user service cards into groups according to the type of interactive service provided. Thus, there may be a service allocation server lor movies only, tor games, and tor catalogs. The service allocation servers act as intermediaries between the call set-up server and the video provider elements whether they be analog user service cards, digital user service cards, trame server web browser applications 206h or MPEG-to-video decoder cards 208. The service allocation servers provide distributed management. The call set-up server 80 can pass the call set-up to the appropriate service allocation server As the service allocation server identities a video provider element and completes the connection with the home intertace controller, the call set up server can be attending to the next caller.

The communications gateway 83 acts as a translator between the IHOP 85 and the back end 1 1 LAN connecting the distnbuted processes ot the system manager. The communications gateway 83 translates the IHOP address trom an individual user into a global Internet Protocol (IP) address tor addressing ethernet data packets within the back end LAN. IP is part ot TCP/IP. Communications are directed trom the communications gateway 83 to the application process directly. Once the service allocation server assigned to a home intertace controller has put the home intertace controller in communication with the requested application process, the communications can be handled directly. System management is also required to maintain administrative tasks such as billing. Each ol the service application processes is in communication with a transaction interface process so that billing and credit and other tinancial matters can be taken care ot.

Fig. 10 illustrates a flow diagram tor a call set-up and tear down procedure as shown in Fig. 9. In Fig. 10. step 91 indicates that a request tor an interactive service from a home intertace controller is made on a hailing trequency. The hailing trequency need only occupy a relatively small bandwidth at a relatively low earner trequency (compared to ordinary television signals) In step 92. the gateway receives the request from the user and transmits a pπvate trequency (approximately 25 kHz bandwidth) assignment to the home intertace controller to be used tor upstream data. Instead ot a pπvate trequency, the gateway may transmit the trame server common channel or this channel may be a default initial channel without need tor notification In step 93, the gateway also converts the private address to an IP address, as discussed in relation to Fig. 9. In step 95. the system manager hands ott to the call set-up server, and in step 951 , the call set-up server hands ott to the service A (tor example) allocation server In step 952, the service allocation server hands ott to the video path manager to identity an open TV channel to assign to the home intertace controller. In step 953. the video path manager hands ott to service A application process to identity an available user service card to run service process A and to assign to the home intertace controller requesting the requested service. In step 954, the assigned user service card provides an interactive menu and, it selected, Internet Web service is provided via an application support server (proxy server). Step 96 indicates that a newly requested service is handled by service A allocation server. It a new service is requested, then in step 97 the service A allocation server hands oft to the call set-up server, and in step 98 the call set-up server hands ott to the appropriate service allocation server. Step 99 indicates that additional processing maybe necessary, depending upon the requested service (as discussed in relation to Fig. 9). Application processing is terminated in step 991 when the interactive service is completed, whereupon in step 992 the assigned TV channel is returned to the pool ol available channels to the video path manager. Also, upon completion ot the interactive service, the assigned user service card is also made available to the pool ot available service application processors. In step 994, the assigned trequency is returned to the pool of available frequency assignments so that the gateway can re-use the trequency for upstream data trom another home intertace controller

Further details regarding system management and the use ol service allocation servers therein can be tound in PCT Application No WO 98/26595. published June 18. 1998. entitled "System Manager and Hypertext Control Interface lor Interactive Cable Television System^", the lull disclosure ot which is hereby incorporated by reterence herein.

Fig. 1 1 indicates the trequency spectrum of the various signals used by the television system. The spectrum to the lett ot the lelt-to-πght arrow in Fig. 1 1 indicates upstream data, whereas the spectrum to the nght ot the πght-to-lelt arrow in Fig. 1 1 indicates downstream data. Interactive channels (NTSC video or MPEG2) are in channels 74-79 (522 MHZ to 552 MHZ). Upstream data has a small bandwidth of 25 kHz in the frequency range ot 5 MHZ to 40 MHZ.

Fig. 12 shows a high-level diagram ot the home intertace controller in communication with the back end. In this embodiment, downstream data is in the form ot packet data on a 300 Kbps data channel. When providing upstream data, the home intertace controller uses a dedicated upstream channel requiπng only a 25 kHz bandwidth tor each home interface controller, so as to provide noise immunity. Fig. 12 is similar to Fig. 1 1. except that a common upstream channel is used by all the home interface controllers tor hailing the back end. No earner or collision detection algorithms are employed, but rather, any lost requests due to collisions among the home interface controllers are "detected" by an absence of response trom the back end atter a suitable time-out. This common upstream channel is used only briefly during an initial log-on to request a pπvate data channel, where the pnvate data channel is indicated in Fig. 13. As an alternative to the use ot a hailing channel, the system manager may include an arrangement tor the periodic broadcast, trom the headend over a downstream portion ot the data link to the home intertace controllers, identifying ot available channels: in this embodiment, each home intertace controller has a rule lor picking one ot the available channels tor use by the transmitter ot its data transceiver.

Claims

What is claimed is:

1 A cable system headend connected to an intormation service distribution network, tor dehvenng information services to subscriber televisions each associated with a home intertace controller, the headend compπsing: a plurality ol interactive controllers each lor receiving data communications trom an assigned home intertace controller and lor generating information signals to be supplied over television signals through the information service distribution network to the subscriber television ot the assigned home intertace controller; a trame server for interfacing with a plurality ot home intertace controllers assigned to said trame server tor interactive service, said frame server generating interactive pages to be supplied to the subscriber televisions associated with the assigned home interface controllers in digitally encoded television signals over the information service distπbution network and receiving data communications trom the assigned subscnbers and a system manager in data communication with the home intertace controllers for assigning said trame server or one ot said plurality ot interactive controllers to a home intertace controller requesting interactive service.

2 The cable system headend ot claim 1 wherein the information service distribution network comprises a plurality ot cables each serving a difterent service area and further compπsing a switch tor directing each television signal trom one ot said plurality ot interactive controllers to the cable serving the service area in which the respective assigned home interface controller is served

3 The cable system headend ot claim 2 turther compπsing a common channel transmitted throughout the intormation service distπbution network tor carrying the digitally encoded television signals trom said trame server.

4. The cable system headend ot claim 1 wherein the interactive pages generated in said frame server are individually addressed to the assigned home intertace controllers.

5 The cable system headend ot claim 1 lurther compnsing a common channel transmitted throughout the intormation service distπbution network for carrying the digitally encoded television signals trom said trame server

6 An interactive cable system compnsing:

(I) an intormation service distnbution network, tor dehvenng intormation services trom a headend to subscnber televisions;

(u) a plurality ol home interface controllers, each home interface controller associated with a subscriber television and having a data transceiver operative over a data communications link to the headend:

(in) a plurality ot subscnber selection devices, each such device associated with a home intertace controller and in communication with the data transceiver thereof:

(IV) a plurality ot interactive controllers, disposed at the headend, in assignable data communication with an assigned home intertace controller and in television communication over the network with the subscnber television associated with the assigned subscπber television: and

(v) a lrame server tor interlacing with a plurality of home intertace controllers assigned to said trame server for interactive service, said trame server generating interactive pages to be supplied to the subscriber televisions associated with the assigned home intertace controllers in digitally encoded television signals over the intormation service distnbution network and receiving data communications trom the assigned subscπbers

7 The interactive cable system of claim 6 wherein each ot said home interface controllers includes a cursor control program responsive to signals trom the associated subscπber selection device tor displaying a cursor and moving the cursor on an image displayed on the associated subscπber television.

8. The interactive cable system ot claim 6 wherein said intormation service distribution network comprises a plurality ot cables each serving a difterent service area and wherein the interactive cable system turther comprises a switch tor directing each television signal from one ot said plurality of interactive controllers to the cable serving the service area in which the respective assigned home interface controller is served.

9 The interactive cable system of claim 8 turther comprising a common channel 5 transmitted throughout said information service distribution network tor carrying the digitally encoded television signals trom said frame server.

10. The interactive cable system ot claim 6 wherein the interactive pages generated in said lrame server are individually addressed to the assigned home intertace

10 controllers.

1 1. The interactive cable system of claim 6 further compπsing a common channel transmitted throughout said intormation service distπbution network tor carrying the digitally encoded television signals trom said frame server.

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