US 20090241144 A1
A full service television system and method are provided. The system comprises a cable headend, at least one fiber transport, at least one distribution hub, at least one hybrid fiber coax plant, and a plurality of set-top terminals. The system delivers television programs, advanced cable services, and online services. Programs and services are transmitted to the set-top terminals in both digital and analog formats to maintain downward compatibility with existing systems. The set-top terminal includes a central processing unit, a unified memory architecture, a memory management unit, communications circuitry, I/O control circuitry, and audio and video output circuitry. Through these components, the set-top terminal provides advanced cable services such as a comprehensive channel navigator, an interactive program guide, one-touch recording, recording conflict detection and resolution, and advanced configuration controls. The set-top terminal also provides online services such as World Wide Web browsing, Internet e-mail, and home shopping.
1. A method of recording at least one television program using an interactive program guide, the interactive program guide having displayable information pertaining to a plurality of television programs, the method comprising:
displaying the interactive program guide on a display;
highlighting on the display information in the program guide pertaining to a selected television program;
receiving a single record-key actuation; and
in response to receiving only the single record-key actuation, automatically recording the selected television program when the selected television program is broadcast.
2. The method of
3. The method of
4. The method of
5. The method of
automatically determining whether the recording of the selected program will exceed capabilities of apparatus operative to record television programs; and
in response to automatically determining that the capabilities of the apparatus will be exceeded, generating the banner indicating a recording conflict.
6. The method of
7. The method of
8. The method of
automatically determining whether any portion of the selected program to be recorded is to occur simultaneously with any portion of at least one other television program to be recorded;
in response to automatically determining that portions of two or more television programs are to be recorded simultaneously, automatically determining whether capabilities of recording apparatus to record portions of two or more television programs simultaneously will be exceeded; and
in response to automatically determining that the capabilities of the recording apparatus will be exceeded, generating the banner indicating a recording conflict.
9. The method of
10. The method of
11. The method of
12. A method of recording at least one television program using an interactive program guide, the interactive program guide having displayable information pertaining to a plurality of television programs, the method comprising:
receiving a record-key actuation pertaining to a selected television program having information in the interactive program guide highlighted on a display;
retrieving broadcast information from the interactive program guide pertaining to the selected television program;
determining whether a television program recorder has previously-programmed broadcast information that conflicts with the retrieved broadcast information;
in response to determining that no conflict exists:
programming the television program recorder with the broadcast information retrieved from the interactive program guide to record the selected television program when the selected television program is broadcast, and
displaying an indicator on the display confirming acceptance of the selected television program for recording; and
in response to determining that a conflict exists, displaying a plurality of actuators for resolving the conflict.
13. The method of
14. The method of
15. The method of
canceling the most recent record-key actuation;
accepting the most recent record-key actuation and canceling conflicting previously-programmed broadcast information; or
entering a general setting menu to modify previously-programmed broadcast information.
16. A method of recording at least one television program using an interactive program guide, the interactive program guide having displayable information pertaining to a plurality of television programs, the method comprising:
displaying the interactive program guide on a display;
highlighting on the display information in the program guide pertaining to a first selected television program;
receiving a first record-key actuation;
automatically programming recording apparatus to record the first selected television program when that television program is broadcast;
highlighting on the display information in the program guide pertaining to a second selected television program;
receiving a second record-key actuation;
automatically determining whether the recording of the second selected program will exceed capabilities of the recording apparatus;
in response to determining that the capabilities of the recording apparatus will not be exceeded, automatically programming the recording apparatus to record the second selected television program when the second selected television program is broadcast; and
in response to determining that the capabilities of the recording apparatus will be exceeded, displaying a banner indicating a recording conflict.
17. The method of
18. The method of
19. The method of
20. The method of
This is a continuation of U.S. patent application Ser. No. 10/882,099, filed Jun. 29, 2004, now U.S. patent Ser. No. ______, which is a continuation of U.S. patent application Ser. No. 09/185,179, filed Nov. 3, 1998, now U.S. Pat. No. 6,772,433, which is a continuation of U.S. patent application Ser. No. 08/802,833 filed on Feb. 19, 1997, now U.S. Pat. No. 5,850,218. The content of each of these applications is incorporated by reference herein.
The invention relates generally to television systems. More particularly, the invention relates to full service television systems that use advance storage, communications, and processing techniques to provide a variety of television services including audio and audiovisual programming, advanced navigation controls, interactive program guides, Impulse Pay-Per-View activation, Near-Video-On-Demand programming, Video-On-Demand programming, advanced configuration controls, and online services.
With recent advances in storage, communication, and processing technologies, many present-day television systems are becoming antiquated. This is especially true of many cable television systems. Traditional methods of broadcasting television programs and services in such cable television systems suffer from an inability to deliver a high number of high quality television signals on a single coaxial cable. Many existing television systems also cannot provide the advanced television services desired by their subscribers, such as, for example, a comprehensive channel navigator, an interactive program guide, Impulse Pay-Per-View activation, Near-Video-On-Demand programming, Video-On-Demand programming, and advanced configuration controls. Furthermore, most modern television systems have no provisions whatsoever for supplying services such as World Wide Web browsing, Internet E-Mail, and online services.
In view of the foregoing, it would be desirable to provide a full service television system capable of delivering a high number of high quality television signals.
It would also be desirable to provide a full service television system capable of using advanced communication techniques to deliver a high number of high quality television signals.
It would further be desirable to provide a full service television system capable of sustaining two-way communication between a cable service provider and a cable service subscriber.
It would even further be desirable to provide a full service television system capable of delivering advanced television services such as a comprehensive channel navigator, an interactive program guide, Impulse Pay-Per-View activation, Near-Video-On-Demand programming, Video-On-Demand programming, and advanced configuration controls.
It would still further be desirable to provide a full service television system capable of delivering services such as World Wide Web browsing, Internet E-Mail, and online services.
It is therefore an object of this invention to provide a full service television system capable of delivering a high number of high quality television signals.
It is also an object of this invention to provide a full service television system capable of using advanced communication techniques to deliver a high number of high quality television signals.
It is a further object of this invention to provide a full service television system capable of sustaining two-way communication between a cable service provider and a cable service subscriber.
It is a still further object of this invention to provide a full service television system capable of delivering advanced television services such as a comprehensive channel navigator, an interactive program guide, Impulse Pay-Per-View activation, Near-Video-On-Demand programming, Video-On-Demand programming, and advanced configuration controls.
It is an even further object of this invention to provide a full service television system capable of delivering services such as World Wide Web browsing, Internet E-Mail, and online services.
In accordance with these and other objects of the present invention, a full service television system is provided that includes digital and analog programs and services, an advanced communications network, and a fully programmable set-top terminal capable of implementing advanced television and online services.
In the preferred embodiments of the present invention, the full service television system is implemented as a cable television system. Although a cable television system is described herein, the present invention, and all of its features, may be implemented in other forms, such as, for example, a Direct Broadcast Satellite (DBS) system, a Multi-channel Multi-point Distribution System (MMDS), an Asymmetric Digital Subscriber Loop (ADSL) system, a Local Area Network (LAN) system, or a Wide Area Network (WAN) system.
Preferred implementations of the cable television system of the present invention include a cable headend, at least one fiber transport, at least one distribution hub, at least one hybrid fiber coax plant, and a plurality of set-top terminals. The cable headend provides programs, services, and overall system control of the cable television system. The fiber transports, distribution hubs, and hybrid fiber coax plants provide an advanced communication network for the cable television system. The set-top terminals provide interfaces, processing, and storage capability in a subscriber's home to facilitate the implementation of advanced television and online services.
To provide programs, services, and overall system control of the cable television system of the preferred embodiments of the present invention, the cable headend incorporates digital and analog satellite receivers, a broadcast cable gateway, integrated receiver decoders, analog scrambling and modulation, application and media servers, an addressable controller, a digital switch or multiplexer, and an interactive cable gateway. Although these elements will be described herein as distinct functions, each can be implemented as a portion of a single device, as a single device, or as a composition of devices.
Programs and services provided by the cable headend are supplied to the cable headend primarily through analog and digital satellite broadcasts and through digital data storage. The cable headend may also receive programs and services from sources such as, for example, analog off-air signals, digital off-air signals, and locally originated signals.
Analog and digital satellite broadcasts are received at the cable headend by a plurality of analog and digital satellite receivers. Integrated receiver decoders within the cable headend control the reception of the analog satellite broadcasts, and analog scrambling and modulation converts the analog signals into a format suitable for transmission over the cable system's communication network. Similarly, a broadcast cable gateway within the cable headend controls the reception of the digital satellite broadcasts and converts the digital signals into a format suitable for transmission over the cable system's communication network.
Programs and services are also supplied to the cable headend through digitally stored data in application and media servers. Programs and services stored in the application and media servers are first transmitted to the cable system's communication network through a digital switch or multiplexer and then through an interactive cable gateway. The digital switch or multiplexer can be implemented through an Asynchronous Transfer Mode switch, a Digital Video Broadcast Asynchronous Serial Interface (DVB ASI), or other suitable means. The application servers can be connected directly to the digital switch or multiplexer, or can be connected to the digital switch or multiplexer via an intermediate network. The media servers, however, should preferably be connected to the digital switch or multiplexer directly because of the high bandwidth requirements of the media servers and the limited bandwidth capabilities of present day networks. Programs and services transmitted through the digital switch or multiplexer from the application and media servers are converted by the interactive cable gateway to a format suitable for transmission in the cable system's communication network. By connecting the application and media servers to the interactive cable gateway through the digital switch or multiplexer, a cable system operator can add new application and media servers to the cable television system as needed.
Overall system control is provided by the cable headend primarily through an addressable controller. The functions performed by the addressable controller can include, for example, control of all equipment interaction at the cable headend, management of the cable television system's communication network, control of all equipment located in the system's communication network, configuration and management of set-top terminals (preferably both those of the present invention and those that may later be introduced into the marketplace), operational control of the distribution hubs, operational control of the interactive cable gateway, and distribution control of programs and services from the integrated receiver decoders, broadcast cable gateway, application servers, and media servers to the set-top terminals.
The communication network of the cable television systems of the preferred embodiments of the present invention includes at least one fiber transport, at least one distribution hub, and at least one hybrid fiber coax plant. The communication network preferably includes analog channels with vertical blanking interval (VBI) signals, forward application transport (FAT) channels, forward data channels (FDC), and reverse data channels (RDC). Analog channels with VBI signals maintain downward compatibility with existing cable television equipment. FAT channels provide set-top terminals with compressed digital content such as, for example, video, audio, applications, control message, and broadcast data. Forward data channels carry to the set-top terminals out-of-band Internet protocol (IP) datagrams containing messages regarding, for example, conditional access, entitlement, broadcast data, network management, application downloads, variable bit-rate (VBR) downloads, external device data services, or general matters. Furthermore, all interactive program guide data is carried to the set-top terminals exclusively over the out-of-band forward data channels. Reverse data channels carry IP datagram messages from the set-top terminals to equipment within the cable headend. These messages can relate to, for example, network management, external device data services, program/service control and activation, or general matters.
The fiber transports carry signals between the cable headend and the distribution hubs and are preferably each physically configured in a ring connecting typically five distribution hubs to the cable headend. Each of the fiber transports includes a bundle of at least one fiber optic cable, at least one of which is used by each distribution hub on the physical ring of each fiber transport. By using selected fiber optic cables within the fiber transport's bundle, the distribution hubs may be connected to the cable headend either through adjacent hubs in a logical “ring” configuration, directly to the headend in a logical “star” configuration, or in any other logical configuration.
The distribution hubs comprise a plurality of data channel gateways, each of which receives and transmits data messages between the cable headend and the set-top terminals. The data channel gateways provide routing functions, modulation functions on the signals to the set-top terminals, and demodulation functions on the signals from the set-top terminals. The routing, modulation, and demodulation functions performed by the data channel gateways are all controllable by the addressable controller within the cable headend.
The hybrid fiber coax plants connect the distribution hubs to the set-top terminals and each includes fiber optic cable, a node, and a plurality of coaxial cables. The node in each hybrid fiber coax plant converts optical signals to electrical signals and electrical signals to optical signals such that two-way communication is maintained over the fiber optic and coaxial cables connecting the distribution hubs and set-top terminals.
The digital and analog programs and services furnished by the cable headend are presented to cable subscribers by set-top terminals within their homes. In the preferred embodiments of the present invention, the set-top terminals each include a central processing unit, memory, a memory management unit, communications circuitry, I/O control circuitry, and audio and video output circuitry. Each set-top terminal is controlled by the central processing unit which executes operating system and application software stored within memory. The memory management unit simplifies and oversees the interaction between the central processing unit and memory. Communication circuitry in the set-top terminal receives, demodulates, decrypts, decodes, and descrambles programs and services transmitted by the cable headend. Additionally, the communication circuitry also controls the two-way digital data transmissions between the headend and the set-top terminal. Input/output (I/O) control circuitry controls subscriber interaction with the set-top terminal through a keypad, an LED display, and a remote control. The I/O control circuitry also interfaces the set-top terminal with an accessories bus and external equipment (e.g., via an I/R transmitter), and is compatible with known interfaces, such as, for example, Ethernet 10-base-T, P1394, and SPDIF. Audio and video control circuitry in each set-top terminal provides graphics generation, audio synthesis, and real-time digital video processing, and generates the outputs necessary to interface the set-top terminal with a subscriber's home audio and video system. These audio and video outputs can include, for example, AC-3 audio, baseband audio, RF video, S-Video, and baseband video outputs.
In the preferred embodiments of the present invention, application software within the set-top terminal provides the advanced cable services desired by many cable subscribers. These services include a comprehensive channel navigator, an interactive program guide, Impulse Pay-Per-View activation, Near-Video-On-Demand programming, Video-On-Demand programming, and advanced configuration controls. Additionally, because the set-top terminal is upgradable via software downloads from the cable headend, new services can be added to the set-top terminal as they become available.
The comprehensive channel navigation controls provided by the application software of the set-top terminal enable a subscriber to more easily navigate through the abundance of programming and services that are available in the preferred embodiments of the present invention. For example, a program information banner can be displayed whenever a subscriber changes channels to identify the program currently being displayed on the selected channel. This banner can include the following: the channel's call sign, number, and logo; the program's name, running time, and elapsed time; the current time; a brief description of the program; information regarding the next program on that channel; or any other information that may be of interest to the subscriber.
The navigation controls of the preferred embodiments of the present invention provide a channel selection function that includes a plurality of tables that cross reference channel numbers with the type, source, parameters, and description of the various television services (e.g., audio and video programming and online services) provided by the cable system. These tables create levels of control, transparent to the subscriber, that allow the set-top terminal to identify the parameters and software needed to activate the program or service associated with a selected channel number. For example, if a subscriber selects channel 10, which is associated with an E-mail service, the set-top terminal accesses the cross-reference tables to identify the type and source of the television service associated with channel 10. The set-top terminal then obtains from the tables any necessary parameters and executes the appropriate E-mail software to activate the selected service. Thus, rather than just map channel numbers to analog broadcast video frequencies as in traditional cable systems, these tables allow channel numbers to be mapped to other sources of data, such as, for example, MPEG video, VBI, IP, and ROM.
Furthermore, unlike traditional cable systems in which channel numbers are fixed to analog broadcast frequencies, these cross-reference tables allow television services to be arranged in any channel number order, regardless of how they are transmitted by the cable system to the set-top terminal. For example, a channel table can be configured to associate channel 4 with video service 3 provided by video source 2 or, alternatively, channel 4 can be associated with music service 12 provided by music source 8. Once a set-top terminal channel number is associated with a particular service, the association is maintained even if the cable provider reassigns the cable channel numbers over which the television services are transmitted.
The preferred embodiments of the present invention also provide channel setting controls which enable a subscriber to fully configure the set-top terminal to operate as desired. For example, the subscriber can assign channels to a favorite channel list; block channels based on channel number, time, program rating, genre, etc.; set timers to record a particular program; turn the set-top terminal on or off at a particular time; or remind the subscriber that a particular program is on or that a tape has to be put in an attached video cassette recorder (VCR).
A browse feature is also provided by the comprehensive navigation controls in the preferred embodiments of the present invention. The browse feature presents a banner that can identify other programs or services that are, were, or will be available for viewing on other channels. Similar to the program information banner described previously, the browse banner can include the following: a channel's call sign, number, and logo; a program's name, running time, and elapsed time; the current time; a brief description of the current program; information regarding a program following the browse program; or any other information that may be of interest to a subscriber.
An interactive program guide within the set-top terminal of the preferred embodiments of the present invention further allows the subscriber to easily operate the set-top terminal and navigate through the abundance of programs and services available in the cable television system. This interactive program guide can include any of at least three main modes: a time mode, a theme mode, and a title mode.
In the time mode, program information is displayed in a grid arrangement with rows preferably corresponding to channel numbers, and columns preferably corresponding to times. By navigating through this grid, a subscriber can identify and review information regarding programs that were, are, or will be available for viewing.
The theme mode of the present invention displays program information of programs that were, are, or will be available for viewing based on a subscriber-selected theme category. Once a theme category has been selected, all programs within that theme are displayed to the subscriber. In some embodiments of the present invention, in addition to scrolling through programs corresponding to a selected theme, a subscriber can also scroll to other themes after reaching the end of the list of programs corresponding to the selected theme.
Similar to the theme mode, the title mode lists and displays information regarding programs available for viewing based on the titles of the programs. Once a first letter is selected, all programs having titles beginning with that letter that were, are, or will be available for viewing are displayed to the subscriber. As with themes, in some embodiments of the present invention, a subscriber is not limited to viewing only those programs with titles beginning with the selected letter, but rather the subscriber may scroll to program titles beginning with other letters once an end of the program titles beginning with the selected letter has is been reached.
All modes of the interactive program guide of the preferred embodiments of the present invention can include a highlighted channel banner, a highlighted program summary, a program viewing window, and mode indicators. The highlighted channel banner preferably indicates the call sign, channel number, and channel logo of the channel highlighted in the interactive program guide display. The highlighted program summary preferably indicates the title, running time, description, and characteristics of the program highlighted in the interactive program guide display. The program viewing window can display, for example, any of the following: the program being viewed prior to entering the interactive program guide, a program selected from the interactive program guide, or a program selected at the headend. The content of the program in the program viewing window can include any of the programs or services which can be displayed by the set-top terminal. The program viewing window can also include a time and channel banner indicating the current time and the channel being displayed in the program viewing window. The mode indicators can indicate the current mode of the interactive program guide and how to activate other available program guide modes.
The interactive program guide of the preferred embodiments of the present invention also facilitates rapid navigation to programs selected by a subscriber. Once the subscriber has found a desired program in the interactive program guide, the subscriber can, by pressing a single key, switch to the program if it is currently being transmitted, set a timer to remind the subscriber of its scheduled transmission, or record the program, either now if currently transmitted or at its scheduled transmission time.
Impulse Pay-Per-View (IPPV) program purchasing is also facilitated in the preferred embodiments of the present invention. Through Impulse Pay-Per-View, a subscriber can request a Pay-Per-View event from the set-top terminal's keypad or remote control. Upon the subscriber selecting an IPPV program, which can be through either the interactive program guide, manual channel selection, or setting of a recording timer, the set-top terminal automatically identifies channels and programs which are IPPV, queries whether the subscriber would like to purchase the selected IPPV program, and authorizes the purchase if the subscriber so indicates. The preferred embodiments of the present invention also allow a subscriber to view summaries of past and currently scheduled IPPV purchases, and to cancel currently scheduled purchases. Additionally, the IPPV features of the preferred embodiments of present invention provide free preview screening of IPPV events, countdown timers to the start of an IPPV event, and automatic reminders if the subscriber has changed channels between the time of ordering and the start time of the IPPV event.
Near-Video-On-Demand (NVOD) can also be implemented in the preferred embodiments of the present invention. NVOD programming transmits each NVOD program from a plurality of sources, each source transmitting the same NVOD program at a fixed time period out of phase with the others. Upon a request to view an NVOD program, the set-top terminal displays on an NVOD channel the source that will next begin transmitting the selected NVOD program based on when the subscriber chooses to view the program.
NVOD programming can simulate the VCR functions of pausing, fast forwarding, and rewinding. This is accomplished by switching the NVOD channel to another NVOD program source. For example, to pause an NVOD program, the set-top terminal displays a pause “barker” (e.g., on-screen message) for the time period between consecutive out-of-phase transmissions of the NVOD program. Once the time period has passed, the set-top terminal switches to the source that began transmitting the program one time period after the previously displayed source's transmission. The NVOD program thus resumes at the point where paused and appears to the subscriber to have been paused by that time period. Similarly, fast forwarding and rewinding are accomplished by switching directly to another NVOD program source. For example, fast forwarding switches to a source that began transmitting the program before the currently viewed transmission, and rewinding switches to a source that began transmitting the program after the currently viewed transmission. By switching to a different NVOD program source, the NVOD program appears to have jumped by the time period between transmissions.
Video-On-Demand (VOD) programming can also be implemented in the preferred embodiments of the present invention. VOD is facilitated primarily by the media servers' ability to deliver high-speed digital data to subscribers' set-top terminals. Upon a subscriber's request to view a VOD event, a media server capable of delivering the VOD event begins digitally transmitting the program to the subscriber's set-top terminal. Unlike traditional broadcasts, this transmission is typically received only by the subscriber who requested the VOD event. A subscriber can therefore view the program at any time, and can also pause, fast forward, or rewind the program being transmitted.
Finally, the preferred embodiments of the present invention also allow messages to be transmitted to one or more subscribers. These messages can be sent to all subscribers (e.g., an emergency broadcast message) or to only one subscriber (e.g., an unpaid balance message). This message system can also send messages from one party within a household to another (e.g., an instruction by a parent to a child) or from one household to another. Thus a local messaging system within the cable system's community can be established. Additionally, these messages can be configured to activate a service at a subscriber's set-top terminal. For example, a set-top terminal can be automatically turned on to display an emergency news broadcast upon receipt of a message from the headend. Thus a subscriber can be alerted by the set-top terminal at any time, regardless of whether the set-top terminal is on or not.
The above and other objects and advantages of the present invention will be apparent upon consideration of the following detailed description, taken in conjunction with the accompanying drawings, in which like reference characters refer to like parts throughout, and in which:
A cable television system 1 of a preferred embodiment of the present invention is shown in
To provide the programs, services, and control of cable system 1, headend 2 includes a plurality of digital satellite receivers 10, a broadcast cable gateway (BCG) 11, a plurality of analog satellite receivers 12, a plurality of integrated receiver decoders (IRD) 13, analog scrambling and modulation circuitry 20, an addressable controller (AC) 14, a plurality of application servers 15, a plurality of media servers 16, a digital switch or multiplexer 17, and an interactive cable gateway (ICG) 18. Although each of these headend 2 elements are described as single functions, each can be implemented as part of a single device, as a single device, or as a plurality of devices.
The programs and services generated by headend 2 are received from four primary sources: analog satellite transmissions from analog service providers, digital satellite transmissions from digital service providers, application programs and services on application servers 15, and media programs and services on media servers 16. Programs and services can also be received at headend 2 from other sources, such as, for example, analog off-air signals, digital off-air signals, and locally originated signals. Analog and digital satellite transmissions typically provide the traditional forms of television broadcast programs and information services. Application servers typically provide, for example, executable code and data for application specific services such as database services, network management services, transactional electronic commerce services, system administration console services, application specific services (such as stock ticker, sports ticker, weather, and interactive program guide data), resource management services, connection management services, subscriber care services, billing services, operation system services, and object management services. Media servers provide time-critical media assets, such as, for example, MPEG-2 encoded video and audio, MPEG-2 encoded still images, bit-mapped graphic images, PCM digital audio, three dimensional graphic objects, application programs, and application data files. Although specific examples of programs and services and the sources that provide them (such as analog and digital satellite transmissions, application servers, and media servers) are given herein, other programs and services, and programs and services from other sources, can be provided to cable system 1 without departing from the spirit and scope of the present invention.
To provide this multitude of programs and services to a subscriber's home on a single coaxial cable, these signals are preferably modulated onto a plurality of 6 MHZ frequency division multiplexed (FDM) channels in the RF spectrum from 5 MHZ through 860 MHZ. More specifically, the 6 MHZ FDM channels in the present invention can be used to carry analog channels with vertical blanking interval (VBI) signals, forward application transport (FAT) channels, forward data channels (FDC), and reverse data channels (RDC). In one embodiment of the present invention, analog channels are in the frequency range of 50 to 500 MHZ, FAT channels are in the frequency range of 500 to 750 MHZ, and FDCs and RDCs are in the frequency ranges of 5 to 40 MHZ and 70 to 130 MHZ, respectively. Although values for the bandwidth, upper limits, and lower limits of these channels are given herein, these values can be altered to suit the individual needs and capabilities of any system in which the present invention is implemented without departing from the spirit and scope of the present invention. For example, 1 MHZ FDM channels can be implemented wherein each of the analog channels, FAT channels, forward data channels, and reverse data channels use different sections of the RF spectrum.
Analog programs and services are received from satellite transmissions in the preferred embodiments of the present invention by analog satellite receivers 12, integrated receiver decoders 13, and analog scrambling and modulation circuitry 20. Analog satellite receivers 12 typically receive the satellite transmissions from the analog service providers in a modulated and scrambled NTSC format. Integrated receiver decoders 13 demodulate and descramble the satellite signals into NTSC signals, and then analog scrambling and modulation circuitry 20 scrambles (using the cable system's scrambling method, if desired) and modulates the NTSC signals onto an analog 6 MHZ FDM channel. The FDM modulation frequencies and scrambling techniques used for the NTSC signals are preferably selected to maintain downward compatibility with analog set-top terminals that may be used with the present invention. The demodulation, descrambling, scrambling, and modulation functions performed by integrated receiver decoders 13 and analog scrambling and modulation circuitry 20 can alternatively be performed by other dedicated devices, such as, for example, satellite receivers, satellite decoders, NTSC scramblers, and NTSC modulators.
Digital services are received from satellite transmissions by digital satellite receivers 10. The signals received by digital satellite receivers 10 typically arrive in quadrature phase shift key (QPSK) modulated, encrypted MPEG-2 transport stream format. Once the satellite transmissions have been received by the digital satellite receivers, broadcast cable gateway (BCG) 11 converts the transmissions signals for transmission over the cable system's communication network under the control of addressable controller 14. broadcast cable gateway 11 demodulates, applies forward error correction (FEC), if desired, and decrypts the satellite transmission to recover an MPEG-2 transport stream. The MPEG-2 transport stream may then be manipulated by BCG 11 to remove unwanted programs from the stream to form an MPEG-2 payload. BCG 11 then encrypts the payload (if desired) and modulates it onto a forward application transport (FAT) 6 MHZ FDM channel. The modulation of FAT channels is preferably 64 or 256 quadrature amplitude modulation (QAM), which enables the channels to carry digital data at rates typically in the range of 27 to 38 Mbps, respectively. By using MPEG-2 payloads, the present invention provides an increase in the number of programs and services that can be transmitted on a 6 MHZ channel over that available with analog technology by digitally compressing and combining a plurality of programs and services into a single MPEG-2 payload.
Application and media programs and services are provided by application and media servers 15 and 16 under the control of addressable controller 14 through digital switch or multiplexer 17, interactive cable gateway 18, and data channel gateways 19 in distribution hubs 4. The programs and services provided by application and media servers 15 and 16 are preferably provided in MPEG-2 transport stream format. Addressable controller 14 may oversee the distribution of programs and services by servers 15 and 16 by processing requests for programs and services from set-top terminals 6, instructing the servers when, where, and how to deliver a requested program or service, and directing the programs and services through the digital switch or multiplexer to the interactive cable gateway and data channel gateways in the distribution hubs.
Digital switch or multiplexer 17 connects servers 15 and 16 to addressable controller 14, to interactive cable gateway 18, and to data channel gateways 19 in distribution hubs 4. Because the programs and services provided by application servers 15 typically do not require high bandwidth, these servers can be connected to digital switch or multiplexer 17 directly (as shown) or via intermediate networks. Media servers 16, however, do require a great deal of bandwidth and accordingly should be connected to digital switch or multiplexer 17 or interactive cable gateway 18 directly until intermediate networks with sufficient bandwidth become available. Furthermore, to achieve their high bandwidth requirement, media servers 16 should incorporate storage devices having interfaces with speeds of at least SCSI Fast and SCSI Wide interfaces, and preferably speeds of Ultra SCSI and fiber channel interfaces.
Interactive cable gateway (ICG) 18 processes the servers' signals so they can be transmitted over the cable system's communication network. Signals received at ICG 18, either through digital switch or multiplexer 17 or from servers 15 or 16 directly, are optionally encrypted, optionally subjected to forward error correction (FEC), and modulated onto a 6 MHZ FAT channel using 64 or 256 quadrature amplitude modulation (QAM).
The analog channels, forward application transport channels, forward data channels, and reverse data channels are transmitted between the cable headend and the set-top terminals over the cable systems' communication network. As shown in
Each fiber transport 3 connects headend 2 to at least one distribution hub 4. Typically fiber transport 3 is physically configured as a ring of bundled fiber optic cables. In this configuration, six cables in the bundle of each fiber transport 3 are typically dedicated to each hub 4 on the ring, and each hub 4 is typically within twenty miles of headend 2. For those hubs 4 that are more than a limiting distance (e.g., more than 20 miles) from headend 2, an intermediate distribution hub 4 may be needed to retransmit the signals in fiber transport 3.
By selecting particular fiber optic cables within the bundle of fiber transports 3, the distribution hubs can be connected to headend 2 through adjacent hubs in a logical “ring” configuration, or directly to headend 2 in a logical “star” configuration. Alternatively, other logical configurations can be used. However, an advantage of the ring configuration is that no distribution hub 4 is cut off from headend 2 by a single break in fiber transport 3.
Hybrid fiber coax plants 5 connect distribution hubs 4 to set-top terminals 6. In a preferred embodiment, hybrid fiber coax plants 5 include a plurality of fiber optic cables 25, a plurality of nodes 26, and a plurality of coaxial cables 27. A plurality of radio frequency (RF) amplifiers (not shown) may also be required at various locations throughout coaxial cables 27 to compensate for losses that occur when the coaxial cable is split to connect each set top terminal. Nodes 26 convert the optical signals in fiber optic cables 25 generated by the distribution hub 4 into electrical signals for transmission on coaxial cables 27 to set-top terminals 6. Return signals from set-top terminals 6 on coaxial cables 27 are converted to optical signals by nodes 26 for transmission in fiber optic cable 27 to distribution hubs 4.
As shown in
One embodiment of set-top terminal 6 constructed in accordance with the present invention is shown in
Controlling the operation of set-top terminal 6 is central processing unit 30. Preferably CPU 30 is a processor that can support 32 bit arithmetic and logical operations, operate at speeds of at least 25 MIPS, and support a system of dynamically prioritizable hardware and software interrupts. An example of a suitable processor for CPU 30 is the SUN Micro-Systems micro-SPARC core. CPU 30 executes instructions stored in memory 32 under the control of an operating system such as the PowerTV Operating System by PowerTV, Inc., of Cupertino, Calif. CPU 30 accesses memory 32 through memory management unit (MMU) 31. MMU 31 provides memory protection for application processes and the kernel, and provides a flat address space for subscriber processes.
Memory 32 comprises non-volatile random access memory (NVRAM), dynamic random access memory (DRAM), flash read only memory (ROM), and read only memory (ROM). NVRAM is used primarily for the storage of subscriber settings and set-top terminal configuration settings, such as, for example, parental control codes, favorite channel line ups, set-top terminal setups, channel maps, authorization tables, and forward data channel address assignments. At least 2K bytes of NVRAM should be provided in memory 32. Dynamic RAM is used for most application and operating system storage requirements, such as, for example, the stack, heap, graphics, interactive program guide data, channel map, VCR codes, marketing data, and usage data, and functions such as MPEG-2 video decompression, AC-3 audio decoding, and video manipulation. At least 3 M bytes of dynamic RAM should be provided in memory 32. Flash ROM is used primarily for the storage of resident application software, as well as patches to the operating system and application software which are downloaded to the set-top terminal from the headend after the set-top terminal has been deployed in the subscriber's home. At least 1M byte of flash ROM should be provided in memory 32. ROM is used primarily for the storage of the operating system. At least 1M byte of read only memory should be provided in memory 32. Although specific purposes for the NVRAM, DRAM, flash ROM, and ROM are illustrated herein, these memory elements can be used for purposes not listed and for purposes listed as corresponding to other elements without departing from the spirit and scope of the present invention.
Frequency division multiplexed (FDM) signals from headend 2 are initially received from hybrid fiber coax plant 5. In-band tuner 41 receives programs and services transmitted to the set-top terminal on analog channels and forward application transport channels. These programs and services include analog programs and services from analog satellite broadcasts, digital programs and services from digital satellite broadcasts, some digital programs and services from application servers, and digital programs and services from media servers. NTSC decoder 38 receives the analog programs and services from in-band tuner 41 and produces NTSC baseband signals. QAM 64/256 demodulator 37 receives the digital programs and services from in-band tuner 41 and demodulates the signal into MPEG-2 payloads. Out-of-band tuner 42 receives only incoming IP datagram messages from headend 2 on the forward data channel. Messages transmitted from the headend to the set-top terminals in Internet protocol datagrams on the forward data channel include interactive program guide data messages as well as other data and control messages. Messages received by out-of-band tuner 42 are QPSK demodulated by QPSK demodulator 39 to reveal the IP datagrams. The analog NTSC baseband signals, the digital MPEG-2 payloads, and the digital IP datagrams are descrambled (if necessary), decrypted (if necessary), and screened by security unit 36. Additionally, security unit 36 provides encryption, key management, authentication, and secure transaction functions, and prevents downloading of viruses by authenticating trusted sources, vandalism of software, theft of services, falsified orders by using electronic signatures, tampering with the set-top terminal, and direct cloning or remanufacturing of the set-top terminal.
After descrambling, decryption, and screening by security unit 36, the baseband signals, MPEG-2 payloads, and IP datagrams are passed on to the analog-to-digital converter 34, MPEG-2 decompress unit 33, and IP router 35. As their names imply, analog-to-digital converter 34 converts the NTSC baseband signals to digital signals; MPEG-2 decompress unit 33 decompresses the MPEG-2 payloads; and IP router 35 routes the IP datagrams toward their ultimate destination.
Outgoing IP datagram messages are also processed by IP router 35. After routing the outgoing IP datagrams, security unit 36 screens and encrypts the IP datagrams (if necessary). The IP datagrams are then QPSK modulated by QPSK modulator 40 and transmitted to hybrid fiber coax plant 5 by out-of-band transmitter 43.
The video and audio outputs of set-top terminal 6 are generated by graphics subsystem 46, audio subsystem 49, NTSC encoder 44, and RF modulator 61. Graphic subsystem 46 produces graphic images and scales MPEG-2 and NTSC video. NTSC encoder 44 generates S-Video output 47 and baseband video output 48 from digitized MPEG-2 and NTSC video. Audio subsystem 49 produces the audio outputs for set-top terminal 6 including AC-3 audio output 50 and baseband audio output 51. RF modulator 61 generates NTSC RF output 45 necessary to drive a television without S-Video or baseband inputs from signals received from NTSC encoder 44 and audio subsystem 49.
I/O subsystem 52 controls input and output functions and the 10-base-T computer interface for set-top terminal 6. As shown in
Additionally, in the preferred embodiments of the present invention, pressing information key 104 from a first channel display 100 causes a program information banner 124 to be displayed on first channel display 100. Similar to program information banners 120 and 122, program information banner 124 can display the current channel's channel number, the current channel's call sign, the current time, the current program name, the program's running time, and the program's elapsed time. Like banner 114, banner 124 may also include information regarding the program following the program currently being transmitted. Pressing information key 104 again with program information banner 124 displayed preferably causes a more detailed program information banner 126 to be displayed on first channel display 100. Unlike banners 114, 122, and 124, more detailed program information banner 126 preferably does not display the running time and elapsed time but rather displays a brief description of the program's contents. As shown, program information banner 126 may omit the current program's name or, as in the preferred embodiments, may include the current program's name.
As an alternative to changing channels using channel up/down key 102 as shown in
In the preferred embodiments, the channel selection function of the present invention includes a plurality of channel cross-reference tables as shown in
Service table 103 preferably indicates the type of service provided. For example, as shown in column 111, services 1-5 are video services, service 6 is a split service (described below), services 12 and 13 are music services, and service 14 is an NVOD service. Optionally, a channel does not have to be associated with a television service, in which case it is associated with “null” service 0 (e.g., channels 8 and 9 are associated with service 0). Other service types, such as, for example, a home shopping service, a still image library service, an online database service, a World Wide Web browsing service, or an E-Mail service, can be added to service table 103 and are represented in service table 103 by “other” service 16.
Service table 103 preferably provides descriptive information for each television service listed. Represented by column 125, this information may include, for example, the service's logo, programming schedule, and program content, and can be used as a source for the program information banners described previously or the browse information banners and interactive program guide described in more detail further below.
Service table 103 further preferably provides parameter references as shown in column 123 for identifying sources of listed television services. The parameter references point to parameter tables, such as, for example, video parameter table 105, split parameter table 107, music parameter table 109, NVOD parameter table 127, VOD parameter table 129, and “other” parameter table 131.
Video parameter table 105 provides application parameters needed to activate video sources 1-9. The content of video sources 1-9 may include, for example, recently released movies, classic movies, science fiction programming, or weather information. Application software parameters are used by set-top terminal 6 (in particular, CPU 30) when executing application software, and may simply include the frequency of a particular source's signals or other more complex variables.
Split parameter table 107 allows a channel to be associated with two or more services, each during different time periods. These services can be of different types and from different sources. For example, if a subscriber selects channel 7, set-top terminal 6 determines from channel table 101 that channel 7 is associated with service 6. From service table 103, set-top terminal 6 determines that the source of service 6 is a split service governed by split parameter table 107. From split parameter table 107, set-top terminal 6 determines that channel 7 is associated with service 10 during time period one (time1) and service 11 during time period two (time2). Set-top terminal 6 then refers to video parameter table 105 to determine the sources and parameters for activating services 10 and 11. Thus, selecting channel 7 will cause set-top terminal 6 to activate source 8 during time period one and source 9 during time period two.
The other parameter tables function similarly to video parameter table 105. Music parameter table 109 identifies sources of music and provides the appropriate parameters for activating these sources. NVOD parameter table 127 provides application parameters for activating a Near-Video-On-Demand service and, similarly, VOD parameter table 129 provides application parameters for activating a Video-On-Demand service. Other Parameter Table 131 is representative of other television service sources and application parameters that can be provided by a cable system of the present invention.
In sum, the cross reference tables of the channel selection function enable set-top terminal 6 to execute software and activate a variety of television services. When a subscriber selects a channel, set-top terminal 6 identifies the type of service associated with the selected channel from channel table 101 and service table 103, and then executes the appropriate program (or special routine within the running program that allows channel selection) to tune in the frequency of the service's source by referring to the appropriate parameter table, descrambling the signal if necessary, and displaying the source's contents on the selected channel. Advantageously, set-top terminal 6 can respond to other types of services that require more interaction. For example, a request to view a channel incorporating a World Wide Web browser results in set-top terminal 6 executing either a resident copy of a Web browser or a downloaded copy from the headend, requesting log-in information from the subscriber, and establishing a browsing session with the headend. Thus the types of services that can be provided to subscribers are not limited by set-top terminal 6. Preferably, new types of services can be added to the cable system's offerings by downloading a new service type module to set-top terminal 6. The cross-reference tables (i.e., channel, service, and parameter tables) are accordingly updated and the new module can then be executed whenever a subscriber selects a channel corresponding to that service.
Furthermore, by configuring set-top terminal channel settings based on entries in service table 103 rather than on entries in channel table 101, changes in the cable channel lineup over which television services are transmitted to set-top terminal 6 do not invalidate a subscriber's set-top terminal channel settings. In other words, the subscriber's mapping of set-top terminal channels to television services is maintained even if the cable service provider reassigns the cable channels over which those services are transmitted. Preferably, when such a reassignment occurs, an updated channel-to-service mapping corresponding to the reassignment is downloaded to set-top terminal 6 to maintain the existing association of set-top terminal channels to television services. Thus, for example, once parents configure channel settings to block particular services deemed inappropriate for their children, a reassignment of cable channels over which those services are transmitted will not affect those services' blocked status. Similarly, other channel settings, such as a subscriber's favorite channel line-up, will also not be affected if such cable channel reassignments occur.
To prevent channel settings from becoming invalid during the lifetime of a set-top terminal, television services listed in service table 103 of a preferred embodiment of the present invention are typically not deleted or replaced. Instead, a new service is assigned to reserved space or space which is dynamically allocated within service table 103.
The manner in which requests for services are made by different applications within set-top terminal 6 are simplified in a preferred embodiment of the present invention by incorporating a uniform resource locator (URL), similar to that on the Internet, to uniformly identify services requested. Services are identified by a URL that incorporates information regarding the format, physical location, logical location, and identity of the service requested (e.g., format://physical/logical/identity). For example, if a service is requested that resides on a server at the headend, the URL identifies the format (e.g., the headend's format), the particular server at the headend, the directory on that server, and the file in that directory. Alternatively, if a service is requested that resides in set-top terminal 6, the URL identifies the format (e.g., code segment format), the physical location (i.e., set-top terminal 6), the particular block of memory, and the memory address of the requested service.
The browse mode of set-top terminal 6 can be exited by pressing channel up/down key 102, by pressing select key 136, by pressing information key 104 whenever more detailed browse information banner 142 is displayed, or by waiting a fixed period of time (e.g., 20 seconds) without pressing any remote control 59 or set-top terminal 6 key. More particularly, pressing channel up/down key 102 with a displayed browse information banner 132 causes the following: the banner is removed from the display, the channel tuner selects and displays the next channel following the previously displayed channel (in this case channel 4 follows the previously displayed channel 3 since the up side of channel up/down key 102 was pressed), and a program information banner 133 is displayed for the new channel as shown in channel display 106. Alternatively, pressing select key 136 with browse information banner 132 displayed causes set-top terminal 6 to tune in and display browse channel 138 and to briefly display a program information banner 140.
The browse information banner can also be used to display information for programs that were or will be transmitted. For example, as shown in
As described in connection with
Although the embodiment of the browse banner shown in
As shown in
A general settings menu 224, as shown in
Once the desired setting has been highlighted by cursor 226, the subscriber may then view or modify contents of the setting by pressing right arrow key 128 (as is indicated by right arrow indicator 246) or select key 136 to move cursor 226 to right half 248 of general settings menu 224. In cases where a setting has not been previously set or the contents of the setting have been erased, an indication such as “(New . . . )” will be displayed in right half 248 of menu 224 to indicate to the subscriber that the setting is empty. When the subscriber has completed using general settings menu 224, the subscriber may exit the menu by pressing settings key 188 to return to previous television display 250. Alternatively to exiting the general settings menu 224, the subscriber may also select another general setting by returning to the left half of menu 224 by pressing left arrow key 128, as indicated by left arrow indicator 244.
Once the subscriber has modified the contents of the VCR timer setting, the subscriber may accept or cancel the modifications as indicated by “A” and “C” indicators 261 and 263. To accept the modified setting, the subscriber presses the “A” application definable key 252. If the subscriber accepts the settings, a cursor will be displayed in list of settings 249 and the modified setting will be displayed as shown in menu 264. To cancel the modified setting, the subscriber presses “C” application definable key 252. Alternatively, if left arrow key 128 is pressed when a cursor is displayed in the left-most column in right half 248 of the general settings menu (as shown in menu 258), any changes to the setting will be canceled. Once canceled, a cursor will be displayed in list of settings 249 and the prior contents of the setting will be displayed.
When the subscriber exits general settings menu 268 by pressing settings key 188 or channel up/down key 102 while leaving behind a conflicting setting, a non-interactive warning window 280 is displayed for a brief period of time (e.g., five seconds) to inform the subscriber of the conflict. To resolve the conflict, the subscriber must press settings key 188 to reenter the general settings menu. Upon reentering the general settings menu, the subscriber is prompted with interactive warning window 272 so the conflict can be resolved using the procedure previously described.
When done reviewing list 290 of past and pending IPPV purchases, the subscriber may press the “A” application definable key 252 to exit. In response, the present invention removes the list from right side 248 of the general settings menu, replaces the list with an updated summary indicator 300, and highlights IPPV Purchases setting 286. In an alternative embodiment of the present invention (not shown), the subscriber may also press “C” application definable key 252 to cancel any IPPV cancellations that were made by highlighting a pending IPPV event and pressing stop key 282.
The favorite channels setting of the general settings menu is shown in
When the subscriber has finished viewing and editing favorite channel list 306, the subscriber may exit the favorite channels setting by pressing “A” or “C” application definable keys 252. Pressing “A” key 252 causes the additions and deletions to be accepted by set-top terminal 6 as shown in general settings menu 318. Pressing “C” key 252, however, causes all changes to be discarded and favorite channel list 306 to remain as it was prior to modification as illustrated in general settings menu 320.
Program grid 366 includes a plurality of rows, each including at least one program cell 396. The number of rows in grid 366 matches the number of displayed channels in channel list 350, and each row in grid 366 is horizontally aligned with the displayed channels in channel list 350 so that the displayed channels act as labels for each row. The size of each cell 396 in grid 366 is a function of the running time of the program identified in that cell. For example, the cell entitled “Encounters” in grid 366 is one half hour long to indicate that the program “Encounters” is one half hour long. Similarly, the cell entitled “Money Line” in grid 366 is one hour long to indicate that the program “Money Line” is one hour long. The start time of each program identified in a respective cell can be determined by referring to the time indicated in date and time bar 348 directly above the leftmost end of each cell. For example, the program entitled “Money Line” begins at 4:30 p.m. as indicated by the time indicator “4:30 p.m.” positioned directly above the leftmost end of the cell identifying “Money Line.”
The subscriber of interactive program guide 338 navigates the program listings of grid 366 to highlight a desired program cell 396 with cursor 394 by pressing up, down, left, and right arrow keys (not shown) as indicated by up, down, left, and right arrow indicators 352, 354, 356, and 358. In the preferred embodiments, cursor 394 is always shadowed in channel list 350 by channel shadow 392 and in date and time bar 348 by time shadow 393. In these embodiments, channel shadow 392 always remains horizontally aligned with cursor 394 to indicate the channel on which the program highlighted by cursor 394 can be found. Similarly, in these embodiments, time shadow 393 always remains vertically aligned with cursor 394 to show the beginning of the time frame highlighted by cursor 394. For example, “KCBS 2” in channel list 350 and “4:00 p.m.” in date and time bar 348 are shadowed by channel shadow 392 and time shadow 393, respectively, to indicate that “CBS Sports . . . ” is on channel “KCBS 2” at “4:00 p.m.”
In the preferred embodiment of the present invention, cursor 394 does not move within grid 366 of the interactive program guide. Program cells 396 of grid 366, call signs 388 and channel numbers 390 of channel list 350, and times 386 of date and time bar 348 scroll instead. For example, as a subscriber presses up and down keys 128 (on remote control 59 or keypad 53 on set-top terminal 6), call signs 388 and channel numbers 390 in channel list 350 and program cells 396 in grid 366 scroll down and up, respectively. As the subscriber presses left and right arrow keys 128, times 386 in date and time bar 348 and program cells 396 in grid 366 scroll right and left, respectively. In the vertical directions, call signs 388, channel numbers 390, and cells 396 scroll one row for each depression of up or down arrow key 128. In the horizontal direction, times 386 and cells 396 scroll one time increment (e.g., one half hour as illustrated) for each depression of the left or right arrow key 128. Alternatively, times 386 and cells 396 can horizontally scroll to the next program cell 396 immediately following the currently highlighted program cell 396 when the subscriber presses right arrow key 128, and scroll to the previous program cell 396 immediately preceding the currently highlighted program cell 396 when the subscriber presses left arrow key 128. After the cells have scrolled up or down, or left or right, the stationary cursor 394 expands or contracts to highlight (preferably entirely) the leftmost program cell, and only the leftmost program cell, that has moved under the cursor's stationary position. Thus, the stationary cursor reacts in the same manner (to highlight the underlying cell) irrespective of the direction of movement of the underlying program grid 366.
As shown in
As described in connection with
After scrolling the contents of grid 366 to highlight a program other than the one currently being displayed, pressing select key 136 causes the interactive program guide to be removed from the display and the channel selection function to select the new program as illustrated by display 410. As shown, a program information banner 412 may be incorporated into display 410 for a fixed period of time (e.g., two seconds) to indicate to the subscriber that the selected program is being displayed. In cases where the subscriber does not wish to switch to a new program, pressing guide key 398 with the interactive program guide displayed causes the display to revert back to original television display 396.
The theme mode display of the interactive program guide is further illustrated in
Once the subscriber has highlighted and selected a theme from theme list 424, set-top terminal 6 replaces theme list 424 with a selected theme indicator 436 as illustrated in
In some embodiments of the present invention, by scrolling through program list 432 the subscriber can see not only those programs within the selected theme, but also programs in other themes. This is facilitated by program list 432 comprising all programs for which data is available and by program list 432 being sorted primarily by program theme. In addition to being primarily sorted by theme, programs in program list 432 may also be secondarily sorted by time and title (as shown) or by any other set of program characteristics. When a subscriber selects a particular theme, set-top terminal 6 displays that portion of program list 432 in which the programs of the selected theme are positioned. The subscriber may then scroll through not only that portion of the list containing the programs of the selected theme but also programs in other theme areas.
By highlighting a desired program in program list 432, information for that program may be displayed to the subscriber. As shown in
Once a subscriber has completed viewing the program list 432, the subscriber may select a program for viewing or alternatively return to the theme list to select another theme. The subscriber may select a program for viewing by highlighting a program with cursor 440 and then pressing the select key (not shown). Set-top terminal 6 then switches to the corresponding channel when the program is a past or current program, or sets a reminder timer when the program is on at some future time. Alternatively, the subscriber may return to theme list 424 to select another theme by pressing the left arrow key (not shown) as indicated by left arrow indicator 438.
The title mode of the interactive program guide of the present invention is illustrated in
By using up and down arrow keys (not shown), as indicated by up and down arrow key indicators 454 and 456, a subscriber can highlight a desired letter with cursor 452 by scrolling alphabet list 448. As with other lists in the present invention, cursor 452 is preferably stationary within the IPG display and list 448 scrolls to make the cursor appear to move with respect to list 448. Once a desired letter has been highlighted, the subscriber may select that letter and enter program list 450 by pressing right arrow key (not shown) or select key (not shown), as indicated by the right arrow indicator 458.
As shown in
In some embodiments of the present invention, a subscriber can see not only those programs beginning with the letter selected from alphabet list 448 by scrolling through program list 450, but also those programs beginning with other letters. This is facilitated by including in list 450 all programs for which data is available and sorting the list by program title. When displaying the list to a subscriber after the subscriber has selected a letter from list 448, set-top terminal 6 centers the displayed portion of list 450 on the portion of the list with program titles that begin with the selected letter.
Once a program has been highlighted using cursor 462, channel banner 344 and program summary 346 each display information for the highlighted program. More particularly, channel banner 344 indicates the channel number, call sign, and logo for the channel showing the highlighted program, and program summary 346 indicates the program title, running time, description, and characteristics for the highlighted program. As with the theme mode display, stars 468 may be displayed adjacent to some programs to indicate that those programs are currently available for viewing. Similarly, other icons can be displayed to indicate other characteristics of the programs in program list 450 such as favorite channel, blocked channel, etc.
Once a subscriber has completed viewing program list 450, the subscriber may select another letter from alphabet list 448 by pressing the left arrow key (not shown) as indicated by left arrow indicator 468. Alternatively, by pressing the select key (not shown) when any program is highlighted by cursor 462, the program guide switches to the corresponding channel if the program is a past or current program, or sets a reminder timer if the program is on at some future time.
As discussed in connection with the general settings menu (see
The One-Touch Recording feature of the present invention also automatically warns the subscriber if an attempt is made to record an Impulse Pay-Per-View program without having previously made arrangements to purchase the program. As shown in
In addition to the information normally available in the program summary of the interactive program guide of the present invention, additional information may also be requested for a highlighted program by the subscriber pressing the information key on the set-top terminal or its remote control.
The information displayed in the interactive program guide of the present invention may be sent to set-top terminal 6 from headend 2 in at least three ways. First, the information may be periodically transmitted to set-top terminals 6, whereby the terminals store the information in their internal memory for use when necessary. Second, the information may be continuously transmitted to set-top terminals 6, whereby the terminals need not store the information in their internal memory, but rather accept the information required for display and discard all of the rest as the information is received. Third, the information may be requested when needed by a set-top terminal 6 over the return data channel of the present invention, after which headend 2 transmits the requested information back to the set-top terminal. Additionally, combinations of these approaches can also be implemented. For example, a week's worth of data can be regularly transmitted by the headend and stored in the set-top terminal's internal memory for display on demand by the subscriber. Other data, however, can be specifically requested by the set-top terminal when the subscriber wishes to view program information not regularly stored in the set-top terminal. Alternatively, rather than requesting the not-regularly-stored information, the terminal can wait for the data to be transmitted in an approach similar to the second approach above. As another example, the program summary data can be received and stored in the terminal's internal memory on a regular basis, with any full description information being requested from the headend by the set-top terminal as required.
Preferred embodiments of the present invention incorporate a method for canceling pending IPPV purchases as illustrated in
The free preview feature of the present invention is illustrated in
Preferred embodiments of the present invention also provide for the operation of Near-Video-On-Demand (NVOD) programs. NVOD allows a program to be viewed more frequently than traditional IPPV events. This is accomplished in the present invention by transmitting the same program using two or more sources, each beginning a fixed period of time after the others. For example, transmitting an hour long program on four channels, each fifteen minutes apart, allows the program to be viewed beginning every fifteen minutes. In this way, the video is near on demand—the prospective subscriber only has to wait at most fifteen minutes to view the program.
A pause feature is incorporated into the NVOD feature of the preferred embodiments of the present invention as illustrated in
Similarly, NVOD provides skip forward and skip backward capabilities as well. As illustrated in
The present invention also incorporates a message transmission system. Messages may be sent from headend 2 to one or more subscribers at one or more set-top terminals 6, or may be sent from one subscriber within a household to another (e.g., automatic message from mother to son sent every Monday night at 8:15 p.m.: is “take out trash”). The messages may be displayed upon the occurrence of a predetermined action by the subscriber or immediately by overriding whatever channel was previously being viewed by the subscriber. For example,
One skilled in the art will appreciate that the present invention can be practiced by other than the described embodiments, which are presented for purposes of illustration and not of limitation, and the present invention is limited only by the claims which follow.