TWO WAY CABLE SYSTEM WITH NOISE-FREE RETURN PATH REFERENCE TO RELATED APPLICATIONS This application is a Continuation in Part of Application Serial No. 09/541, 187 filed April 3, 2000 to the applicant of the present application.
FIELD OF THE INVENTION
This invention relates to cable systems and more particularly to such systems with a sufficiently noise free return path to support high bandwidth two-way broadband, multimedia content delivery to and from the home.
BACKGROUND OF THE INVENTION It is well known that the return path in a cable system is noisy and is frequently referred to as a "noise funnel". There are three primary sources of such noise: Thermal, fiber optic link and ingress. Thermal noise is generated in each of the active components (amplifiers and receivers). The fiber optic link noise is generated in the return laser, fiber and headend receiver. Ingress noise arises through home wiring and connections and constitutes the major source of noise. A complete discussion of the return path and the noise characteristics is provided in "Return Systems for Hybrid Fiber/Coax Cable TV Networks" by Donald Raskin and Dean Stoneback, 1998 Prentice Hall, Inc.
Traditional cable systems have a major trunk along which signals are transmitted from a headend in a forward direction to set-top boxes located in homes or business facilities connected to the feeder lines. Connection of set-top boxes to a feeder line is provided by connecting each set-top box to the feeder line via a tap. In the usual organization of a cable system there are many set-top boxes connected to each feeder line. Moreover, each feeder and/or trunk line includes bi-directional amplifiers which pass signals in a high frequency band in the forward (downstream) direction, and in a low
frequency band in the return (upstream) direction, which is well understood in the art. Signals in the low frequency band originate at set-top boxes and are used to communicate in the upstream direction to the headend.
The problems with present return paths in cable systems arise from the fact that the path from the set-top to the tap in the feeder line (the inside wiring and the drop) is characterized by an unacceptable level of noise (ingress) which is picked up in the home wiring and in drop cable in the low frequency band where the set-top box transmits. Further, no other band (relatively free of such ingress noise) in a low-split cable system is available for transmission from the home to the headend. Present low-split cable systems are wedded to transmission from the cable headend in a high frequency band and transmissions from set-top boxes in a low frequency band.
Yet the financial expectations of two way, broadband channels via a cable system are so compelling that significant resources are being dedicated towards solving the ingress noise problems in the return paths. The present remedial solutions are expensive, cause system shut down, cause system instability, require repeated service calls to subscribers facilities, and frequent home and drop rewiring or installation of special traps. Moreover, with corrosion and deterioration of lines and connectors, there is a high likelihood that continued attention by cable operators will be necessary.
In the last ten years the cable industry has been retrofitting its cable infrastructure to allow for two-way communications on the cable plants. This is referred to in the industry as activating the return path; the return path being in the 5-40 MHz frequency band. The design of the return path started with rebuilds in the late 70's. In the late 80's the larger cable companies began to segment their service area into smaller groups called "nodes", and changed their trunk system in many cases from using just co-axial cable and
trunk amplifiers to a hybrid fiber/co-axial cable system (HFC). At the same time active and passive devices were replaced to increase the frequency spectrum in the downstream direction from 50-350 MHz plants to 50-750 MHz, in some cases up to 850 MHz. The increased downstream frequency band allows cable companies to offer more channels of video services. The increased bandwidth also can be used for digital services in the forward direction. Also, by now activating the return path, two-way services such as impulse pay-per view, interactive TV, cable modems, telephone service, and additional services can be offered.
In the activation of the return path, it has been found by most of the cable companies, that the 5-40 MHz frequency band, especially the 5-15 MHz spectrum is extremely noisy. Because of the presence of the noise, most of the services presently available in the lower frequency band are digital services that can often work with low carrier to noise signal levels. But since the noise is not consistent, services are seriously impaired at times. Thus, a large number of cable companies are currently looking for ways to reduce the noise in the 5-40 MHz frequency band. Most of the approaches have been to reduce the number of homes connected to each node thereby reducing the total accumulated noise collected in each segment of the node. There have also been approaches involving the installation of 5-50 MHz blocking filters to reduce the noise from inactive subscriber's homes in the 5-50 MHz frequency band from entering the main cable distribution network. The current best approach is to divide the cable system into many nodes which service as few as fifteen homes which is in effect providing a system of small clusters of homes, each connected directly to the node. BRIEF DESCRIPTION OF THE INVENTION
The present invention is based on the realization that a portion of the downstream frequency band (i.e. 50-750 MHz) can be used, in part, to carry the return path signal from a set-top box. That portion of the frequency band is presently used to provide TV signals and digital signals from the headend to the home. But that portion of the band cannot presently be used to carry return path signals.
In accordance with the principles of this invention, the noise picked up in home appliances, drops, connectors, etc and transported to the corresponding node in the feeder line is avoided by reconfiguring the set-top box to transmit in the high frequency band rather than in the low frequency band where most of the noise occurs. The signals from the set-top box proceed in the downstream direction to the feeder line end, which in addition is equipped with a receiver (optical transmitter) and a fiber back to the node or directly to the headend. The result is that set-top box transmissions travel in the forward direction to the feeder line end where they are received and transmitted (optical transmitter) via a fiber to the node or the headend. The noise (home to feeder line tap) is avoided since the lower frequency band in which the majority of the ingress noise is located is not utilized. In this context, each feeder line end has terminator(s) and the receiver (i.e. optical transmitter) plus fiber link may be placed just after the last amplifier (terminal) in the feeder line and before the feeder line separates to different line terminator(s). The portion of the feeder line between the last amplifier (terminal) and the position where the feeder line separates line terminator(s) is referred to herein as the feeder line end.
Specifically, applicant herein adds to the cable system relatively inexpensive equipment which permits the set-top box to feeder line end portion of the return path to function as a forward path. This is accomplished, in one embodiment, by providing at
each feeder line end a optical transmitter and fiber link. The optical transmitter receives the signals in the high portion of the band and transmits the signal via a fiber link back to the node or headend. The nature of this system is that it virtually eliminates ingress noise from house wiring and the drop, which is shown schematically on page 57 of the above- noted publication. It provides a further advantage of allowing the system operator to choose the size and location of the return band within the 50-750 MHz frequency spectrum.
In another embodiment, each feeder line end includes a receiver and a demodulator to decode the received data. The decoded data is then used to modulate a new signal. The regenerated signal does not contain the noise that was contained in the received signal. It is in effect a noise free signal. A optical transmitter than send the signal via the fiber to the node or headend.
Thus, in accordance with the principles of this invention, a technique is provided for eliminating the ingress noise in the low frequency band from house wiring, device(s) in the home, and the drop from entering the cable system by not using the lower frequency band where most of the ingress noise resides. Each of the forward amplifiers already has a high pass filter blocking the low frequency band being amplified in the forward direction. The higher frequency band is used to carry the return signal from the feeder line end to the node or the headend. Due to the substantial noise reduction, much higher modulation schemes such as QAM- 16, QAM-32, QAM-64, QAM-256 etc may be employed. Current modulation schemes also become much more reliable and have much lower bit error rates. The return signals are not restricted to modulated signals. All kinds of signals (i.e. video signals, radio signals) can originate from the subscriber locations. Overall it makes the return path in a cable system much more usable. With the resulting higher reliability there
is likely to be fewer customer calls for service and higher customer satisfaction. The size of the return path is totally flexible and the system operator can choose any size and location in the frequency band for the return signal. Furthermore, since the return path for each feeder line end can be brought back separately to the headend, the effective size of the return path for the overall system is substantially larger than the existing system could allow.
This invention, illustratively, utilizes a portion of the 50-750 MHz frequency band to carry the return signal from the subscriber locations, rather than the 5-40 MHz frequency spectrum. But the return signal is transmitted first forward to the feeder line end where it is picked up and brought back to the cable headend. At the end of each of the feeder lines is a receiver that operates, illustratively in the 50-750 MHz band to receive the "return" signal. For example, the 300-350 MHz band could be used to carry the return signal "forward" to the feeder line end. The signals in this band are received by the receiver (i.e. optical transmitter) at the end of the feeder line. The signals are then send via a fiber link to the node or to the cable headend The ingress noise in the lower frequency band is total avoided since the lower frequency band is not utilized. The system also does not require reverse amplifiers and thereby also avoiding the need to align reverse amplifier signal levels that is time consuming and painstaking work. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic representation of a prior art cable system including cable headend, trunk, nodes and illustrative set-top box locations;
Fig. 2 is a graphic representation of portions of the frequency band presently used for cable headend, set-top box, and bi-directional amplifier operation in prior art cable systems;
Fig. 3 is a graphic representation of typical ingress noise levels for transmissions in the low frequency band of Fig. 2:
Fig.4 is a schematic representation of a cable system in accordance with the principles of this iπvemion; Fig's 5A - 50 are graphical representations of portions of the frequency band used for the headend, the set-top box. the bi-directional amplifier, and the optical transmitter of the arrangement of fig 4.
Fig's 6A - 6E and 7A - 7E are representations of signal processing schemes and related graphical representations of portions of the frequency band used for feeder line ends in cable systems in accordance with the principles of this invention;
Fig 8 shows a set of related graphs of signal level versus frequency for a cable headend, a set-lop box, an amplifier and an optical transmitter for a cable system in accordance with the principles of this invention;
Fig 9 shows a graph of ingress noise and portion of the frequency spectrum in which set-top boxes transmit in accordance with the principles of this invention;
Fig 10 is a schematic representation of an alternate embodiment of this invention;
Fig 1 is a set of related graphs of signal level versus frequency for a cable headend, a set-top box, an amplifier and optical transmitter respectively for a cable system in accordance with the principles of this invention; Fig 12 is a graphical representation of a band pass ilter for use in embodiments of this invention; and
Fig's 13, 14, and 15 are schematic representations of a prior art set-top box and alternative set-top boxes useful in embodiments of this invention.
DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS OF THIS INVENTION
Fig. 1 shows a schematic block diagram of a prior art cable system to establish a point of reference and terminology for the description of illustrative embodiments of this invention: Specifically, Fig. 1 shows a cable system 10 with a cable headend 11 and a major trunk 12. Trunk 12 typically comprises a coaxial cable and is connected to node or hubl3. Node 13 is connected to the cable headend via optical fiber (or a coaxial cable) 14 and (for the former) includes a optical transmitter for providing return signals from a subscriber set-top box to the cable headend. The major trunk includes a plurality of bi-directional amplifiers represented, illustratively, at 17 and 18. The trunk also includes bi-directional bridger amplifiers 20 and 21 to which feeder lines 22, 23 and 24 are connected as indicated. Also shown is a auxiliary feeder line 26 which also includes bi-directional amplifiers (represented at 27) and tap 28 to which a drop cable 29 to a set-top box is connected. A trunk cable end terminator is present at the end of trunk 12 as indicated at 30.
The end of a feeder line 24 has line terminators at 31 and 32.
Fig. 2 shows a set of related graphs of signal level versus frequency for the headend, the set-top box, and the bi-directional amplifiers respectively, for a prior art cable system. In the prior art system, the cable headend illustratively, receives signals in the 5-40 MHz band and transmits over the entire, illustratively, 50-750 MHz band. The set-top box operates in just the opposite manner. Specifically, the set-top box transmits in the 5-40 MHz band and receives signals in the 50-750 MHz band.
The bi-directional amplifiers pass signals forward, (away from the headend) in the 50-750 MHz band and pass return (toward the headend) signals in the 5-40 MHz band.
Thus, signals from a set-top box in the 5-40 MHz band occur exactly where most of the ingress noise occurs. Fig. 3 shows a curve 33 representing the accumulated ingress noise with maximum ingress in the 5-40 MHz band. It is clear that the usefulness of the present return path can be severely limited by ingress noise. Fig. 4 is a block diagram of a cable system in accordance with the principles of this invention. The system 40 comprises a headend 41 connected to a node (or hub) 42 by fiber optic (or coaxial) cable 43. The node contains one or more return optical transmitters (for fiber optic systems). The system also includes a major trunk 45 with amplifiers 47 and 48 (there usually are more amplifiers and they are located usually 500- 1500 feet apart) with bridger amplifiers 50, and 52. In one embodiment a feeder line 56 is shown connected to bridger amplifier 50 and line end terminator 58. A high pass filter 59 and an optical transmitter 60 is located between the last amplifier (terminal) 57 and feeder line terminator 58 . The optical transmitter feeds into fiber 91 that goes to node 42. It could be routed directly to cable headend 41 and the principals of this invention would still apply. The frequency spectrum modulating the optical transmitter 60 is shown in Fig. 5A.
In another embodiment, a feeder line 61 has feeder line ends at terminators 62 and 65. A band pass filter 63 and an optical transmitter 64 are located after the last amplifier 53 and before terminators 62 and 65. The band pass filter only passes signals in the 300- 350 MHz frequency band, the frequency band in which the set-top boxes transmit. The optical transmitter 64 feeds the signal into fiber 92 that goes to node 42. The frequency spectrum modulating optical transmitter 64 is shown in Fig. 5B.
Illustrative of a further embodiment, a feeder line 66 has a feeder line end terminator 69 which includes a band pass filter 67, a demodulator 70, modulator 71, and
an optical transmitter 68. The band pass filter only passes signals in the 300-350 MHz frequency band; the frequency band in which the set-top boxes transmit. Only one demodulator is shown in Fig. 4 for illustrative purposes. There can be multiple demodulator and modulator pairs, all separated in the frequency spectrum over the 300- 350 MHz frequency band. The combined output of the modulators can be over any frequency spectrum. In the illustrative embodiment of fig. 4, the modulator 71 output is over the 140-190 MHz frequency spectrum. The frequency spectrum modulating optical transmitter 68 is shown in Fig. 5C. In a further embodiment a feeder line 110 has a feeder end at 80 which includes a band pass filter 81, a frequency band block converter 83 which converts the block of frequency band 300 to 350 MHz to 50 to 100 MHz, and an optical transmitter 82. Again, the band pass filter only passes signals in the 300-350 MHz frequency band; the frequency band in which the set-top boxes transmit. The frequency spectrum modulating optical transmitter 82 is shown in Fig. 5D. Use of a block converter allows different frequency bands to be used for communication back to the node, where the various signal for the feeder line ends are combined together into a single signal but separated in the frequency band, and sent back to the cable headend.
In Fig. 4, fiber 92 is shown connected to node 42. The fiber could be routed directly to the headend with no additional processing of the signal at node 42. The complete frequency spectrum 50-750 MHz could then be received at the headend. This would provide the system operator the capability of checking the quality of the signals sent on the network plus the receive the signals sent back by the set-top boxes.
Fig. 6A shows one possible embodiment of signal processing at node 42 of Fig. 4. In this particular case all the signals received from feeder line ends at node 42 are combined into a signal and the combined signal is carried to the headend via a single fiber
cable. Fig. 6 A shows a fiber input into optical receiver 151. The input to optical receiver 151 could be the signal transmitted on fiber 92 of Fig. 4. Fig. 6B shows the frequency spectrum output of optical receiver 151. The optical receiver 151 output signal is fed into a combiner 155. Similar outputs of optical receiver 152, 153, and 154 are also fed into combiner 155. Fig. 6C shows the frequency spectrum of optical receiver 152. Fig. 6D shows the frequency spectrum output optical receiver 153. Fig. 6E shows the frequency spectrum output of receiver 154. The frequency spectrum output of combiner 155 is shown in Fig.6A. The frequency spectrum of optical receivers 151, 152, 153, and 154 are combined and overlap in the frequency output spectrum of combiner 155. In this particular case only one of the set-top boxes transmits at a particular frequency at the same time. The output of each of the set-top boxes is in-effect time division multiplexed. Fig. 6A shows only four fiber returns but the principal would be the same where the number of return fibers is substantial greater. The output of combiner 155 is fed into optical transmitter 156. The output of optical transmitter 156 is a fiber cable back to the headend. The signal processing at the headend is similar to that of the prior art system. Table 1 shows various other kinds of devices and mediums that can replace an optical transmitter and fiber at the feeder line end and still achieve the same objective of getting the received signals from the set-top box at the feeder line end back to the headend. A person skilled in the art would recognize, that if the device and medium are changed at the feeder line end, a receiver that is compatible with the medium and transmitter device would be required at the cable headend to receive the signal. Any required signal conversion could also be made at the feeder line.
Fig. 7A shows another embodiment of signal processing at node 42 of Fig. 4. In this embodiment the signals received from each of the feeder lines is frequency division
multiplexed into a single signal. The frequency division multiplexed signal is sent back via fiber to the headend. Fig. 7A shows a fiber input into optical receiver 141. The input to optical receiver 141 could be the signal transmitted on fiber 92 of Fig. 4. Fig. 7B shows the frequency spectrum output of optical receiver 141. High Pass Filter 59 of Fig. 4 is operative to receive signals illustratively in the 50 to 750 MHz band. The set-top boxes in the system of Fig. 4 are also operative to transmit in the 50 to 750 MHz band. Thus, transmissions from a set-top box (the return transmissions) are received first by receivers at the feeder line ends before they are transmitted via the fiber link to the cable headend. The principals of this invention would still apply where the optical transmitter and fiber link are changed to a cable amplifier and co-axial cable. Table 1.
It is to be understood that in accordance with the principles of this invention, signals from a set-top box are in a frequency band which travels to a receiver at the feeder line end rather than in a return path to the cable headend.
But each feeder line end, also in accordance with the principles of the invention, includes means for receiving those signals and transmitting those signals back to the node or the cable headend. In the Fig. 4, the means for receiving signals in the 50-750 MHz band are optical transmitters 60, 64, 68 and 82. The optical transmitters feed the signal into the fiber and those signals are received at the node or cable headend.
Fig. 8 shows a set of related graphs of signal level versus frequency for a cable headend, a set-top box, an amplifier, and an optical transmitter respectively for a cable system in accordance with the principles of this invention. As shown in Fig. 8, the headend can receive in the 50-750 MHz band, but does not transmit over the entire 50- 750 MHz band. The 300-350 MHz portion is notched out. The set-top box transmits in the 300-350 MHz portion and receives in the 50-300 MHz and in the 350-750 MHz bands. The amplifiers operate only in the forward direction and carry signal away from the headend. Not having reverse amplifiers removes the necessity of having to align the reverse amplifiers which is time consuming and painstaking work. It is clear from Fig. 8 that signals transmitted by set-top boxes in the system of Fig.
4 are passed in a "forward" direction to the corresponding feeder line end where they are received, and transmitted back to the node or cable headend.
Fig. 9 shows a graph of ingress noise 100, corresponding to that of Fig. 3, along with the portion of the frequency spectrum 300-350 MHz in which set-top boxes transmit in accordance with the principles of this invention. It is clear that ingress noise is insignificant over the portion of the spectrum now used by set-top boxes in the system of Fig. 4, Thereby providing return signals virtually free of ingress noise in the return path to the cable headend.
A system, in accordance with one of the embodiments of the principles of this invention, also includes band stop (notch) filters (i.e. 112) at the start of auxiliary feeder lines (i.e. 110) in the system (of fig. 4) to ensure that transmissions from a set-top box in the 50-750 MHz band are only received by one feeder end in the system. Such a band stop filter 112 is located at the start of auxiliary feeder line 110 to ensure that the signal for each set-top box is received only at one feeder end (i.e. the signal from set-top box 55 is received by band pass filter 67 only, since band stop filter 112 blocks the signals from being received by band pass filter 81.
Fig. 10 shows a system similar to that of Fig. 4 where the bi-directional amplifiers of the prior art system of Fig. 1 are maintained to provide a system where the prior art set- top boxes can continue to function as before in this new combined system that allows for new set-top boxes to transmit in the 50-750 MHz band and prior art set-top boxes to transmit in the 5-40 MHz band.
Fig. 11 shows a set of related graphs of signal level versus frequency for a cable headend, a set-top box, an amplifier, and optical transmitter respectively for a cable system in accordance with the principles of this invention. As shown in Fig. 11, the headend can receives in the 50-750 MHz band and also in the 5-40 MHz as in the prior art, but does not transmit over the entire 50-750 MHz band. The 300-350 MHz portion is notched out. The new set-top box transmits in the 300-350 MHz portion and receives in the 50-300 MHz and in the 350-750 MHz bands. The bi-directions amplifiers operate as before to carry 5-40 MHz signals towards the headend and 50-750 MHz signal in the forward direction away from the headend. This embodiment shows a combined system where the prior art set-top boxes and the novel set-top boxes of this invention operate in a combined system. This combined system offers a solution to cable operators to continue
to serve existing customers with their existing (prior art) set-top boxes and new customer using the set-top boxes in line with the principles of this invention. Thereby retaining the existing system and upgrading the system in line with the principles of this invention.
Fig. 12 shows a graphical representation of a band stop filter which passes signals in the 5-750 MHz band except for signals in the 300-350 MHz (notch) portion of the band. The presence of such filters prevents signals from a set-top box (in the 300-350 MHz band) from being received by more than one feeder end.
Fig's. 13 and 14 show schematic representations of a prior art set-top box and a set-top box in accordance with the principles of this invention, respectively. In the prior art set-top box of Fig. 13, a high pass filter 104 excludes signals in the 5-40 MHz band and passes signals in the 50-750 MHz band. The set-top box also includes a low pass filter 101 which excludes signals in the 50-750 MHz band and passes signals in the 5-40 MHz band.
The set-top box of Fig. 14 is considerably different. Specifically, the set-top box of Fig. 14 includes a band stop filter 102 which passes 50-750 MHz but notches out signals in the 300-350 MHz band. The set-top box also includes a band pass filter 103 which passes signals in the 300-350 MHz band. Thus, the set-top box of Fig. 14 receives and transmits in the same (high) band (i.e. 50-750 MHz) whereas the set-top boxes of the prior art receive and transmit in high and low (considerably different) bands respectively. Fig 14. further shows an optional feature in the set-top box that would allow the set-top box to also transmit a return signal in the low frequency band (5-40 MHz) as done by the prior art set-top box. This optional feature would work with the system of Fig. 10 that allows the headend to receive in the 5-40 MHz band and in the 50-750 MHz band. This
new set-top box would now have two separate frequency bands in which the headend can receive signals from the set-top box.
Fig. 4 also shows an auxiliary feeder line 110 extending from feeder line 66. It is important that a transmission from a set-top box of the system of Fig. 4 be received only by the receiver at the end of one feeder line to which the transmitting set-top box is connected. In order to prevent signals from, for example, a set-top box connected to feeder line 66 being received by a receiver 82 (optical transmitter) connected to an auxiliary feeder line (110), the auxiliary feeder line includes a band stop filter 112 to exclude such transmissions as discussed herein before. Alternatively, the cable headend may be configured to poll (i.e. enable) a set-top box and the corresponding feeder line end optical transmitter simultaneously so that only signals from that receiver are received at the headend. The cable headend will of course, require additional software in this case. This would allow the cable operator to choose the size and location of the return frequency band. Frequency agile band stop filters and frequency agile band pass filters can also be used in the system to utilize any portion of frequency band desired by the system operator. The frequency bands selected herein are only illustrative and other bands and/or notches may be suitable as is clear to one skilled in the art. For example, the operator could use the 700 MHz and up band for the return path. In this case the configuration of the set-top box would change to that shown in Fig. 15. The optional feature shown in Fig. 15 allows this new set-top box to also send signals to the headend via the 5-40 MHz band. This set-top box can communicate with the headend in the 5-40 MHz frequency band and in the 700 MHz and up frequency band.
There are various ways for the signals received at node 42 of Fig. 4 to be brought back to the cable headend 40 of Fig. 4. The embodiment of Fig. 7A shows receipt of fiber
92 of Fig. 4 being received by optical receiver 141. Fig 7B shows the frequency spectrum received by optical receiver 141. The 300-350 MHz frequency band of Fig. 7B is directly mapped to 300-350 MHz frequency band of Fig. 7 A. Fig. 7C shows the frequency band received by optical receiver 142. Block frequency converter 146 of Fig. 7A converts the 300 MHz (fc) to 350 MHz (fd) frequency band to 240 MHz (fd) to 290 MHz (f0) frequency band. The frequency spectrum of optical receiver 141, block frequency converters 146, 147, and 148 are combined by combiner 149. The frequency spectrum output of combiner 149 is shown in Fig. 7A. Fig. 7A shows that each of the feeder line outputs is separate in the frequency spectrum of combiner 149. This allows one set-top box in each of the feeder lines to transmit at the same frequency and at the same time as another set-top box in another feeder line. Thereby provide a substantially higher effective return bandwidth for the cable system.
It is anticipated that the novel set-top boxes shown herein may have wireless capability added to them to allow them to communicated wireless to other devices in the home and business facilities such as personal computers, videophones, telephone etc.
The optical transmitters, optical receivers, high pass filters, band pass filters, band stop filters, converter receivers, transmitters and other components herein are all commercially available or easily configured from available components. Any such components operative as required herein may be used in accordance with the principles of this invention.
It is to be understood that although the invention has been described illustratively in terms of a set-top box, any two-way communication device, such as a cable modem, can be used.