JPH11502069A - General demarcation point - Google Patents

Abstract

A universal demarcation point for managing the delivery of communications services to a subscriber that provides an interface between a utility distribution network and subscriber owned equipment. The universal demarcation point includes a utility accessible portion and a subscriber accessible portion. The utility accessible portion has an input port, an output port, a plurality of modular connectors, a power supply, and a plurality of service modules. The input port provides access to the universal demarcation point for delivery of communications service from the utility distribution network. The communications services are delivered through a hybrid cable. The hybrid cable has a plurality of fiber optic cables and a plurality of copper cables. The fiber optic cables are capable of transmitting light signals and the copper cables are capable of transmitting electric power. The output port provides access for delivering the communications services from the universal demarcation point into the subscriber's dwelling. The plurality of connectors are fixedly mounted to the universal demarcation point. The power supply is removably mounted to the universal demarcation point. The power supply converts the electric power into a voltage for powering the operation of the universal demarcation point. The service modules are capable of plugging into the modular connectors and convert the light signals that are transmitted on the fiber optic cables onto cables that are suitable for use in the subscriber's dwelling. The subscriber accessible portion is adjacent to the utility accessible portion and has ports that enable the subscriber to test the integrity of the communications services delivered from the utility distribution network.

Description

DETAILED DESCRIPTION OF THE INVENTION General purpose demarcation point Background of the Invention The present invention relates to an apparatus for facilitating delivery of a communication service to a subscriber. In particular, the present invention provides a universal demarcation that provides an interface between a utility distribution network and a subscriber-owned device for use in delivering communications services to a subscriber over optical fiber and copper cables. point). When delivering a communication service to a subscriber, it is common for an entity (utility) to attach a service box to the subscriber's residence. The service box provides an interface between the utility distribution network and subscriber-owned devices. As used herein, the term "subscriber-owned device" means a device that a subscriber attaches directly or indirectly to a utility distribution network to send and receive communication services over an enterprise distribution network. Examples of subscriber-owned devices include telephones, televisions and modems. When a subscriber subscribes to many types of communication services, the entity installs a separate service box at the subscriber's residence for each type of communication service. Next, each individual service box is connected to the appropriate utility distribution network. For example, a telephone service box is connected to a telephone distribution network, and a cable television service box is connected to a cable television distribution network. When an entity provides telecommunications services in rural areas where each subscriber may be several kilometers (several miles), the entity installs separate copper wiring for each service box in each subscriber's residence. There must be. Further, when communication services are transmitted over long distances using some type of copper wiring, electrical signals are attenuated and distorted. To overcome these shortcomings, the business must install amplifiers or repeaters at regular intervals in the utility distribution network to provide the desired quality of service to the subscriber. As a result of the costs associated with providing services to subscribers in rural areas, entities have been limited in their ability to provide subscribers with a range of communications services typically available to subscribers in rural areas. There are a variety of service box designs. One such design is described in Grant US Pat. No. 4,673,771. Grant's patent discloses a general purpose building drop-in terminal for telephone service. The terminal is designed primarily for installation in a commercial building where access to a terminal block for attaching, removing, or modifying a subscriber's telephone line is required. The terminal has a modular structure that allows access and modification of components at the terminal. Some service box designs include the ability to deliver more than one type of utility service. For example, US Pat. No. 3,614,538 to Nickola discloses a pedestal mounted adjacent to a mobile home to provide power, telephone and gas services to the mobile home. doing. Conventional power and gas meters, along with conventional telephone booths, can be mounted in place so that the utility is easy to connect and disconnect to mobile homes. U.S. Pat. No. 4,785,376 to Divelly discloses a utility pedestal designed primarily for use in marinas. The pedestal allows for single point delivery of power, telephone, television and water services. The pedestal also includes a connector that allows convenient connection and disconnection of utility service boats or vehicles. Horn US Pat. No. 5,196,988 and Horn US Pat. No. 5,184,279 disclose adapter faceplates used in metal power pedestals. This adapter provides the ability to add telephone and television capabilities to the power pedestal. The adapter insulates telephone and television cables from pedestal electrical components. US Patent No. 5,134,541 to Frouin discloses a distribution system for water, gas, fuel, electricity, and other fluids. The system is sealed in a container that prevents vandalism of the utility service and that accepts the payment. Summary of the Invention The present invention includes a universal demarcation point for managing the delivery of communication services to subscribers. The universal demarcation point provides an interface between the utility distribution network and the subscriber-owned devices. The general demarcation point includes an entity accessible portion and a subscriber accessible portion. The entity accessible portion has an input port, an output port, a plurality of modular connectors, a power supply, and a plurality of service modules. The input port allows a hybrid cable from the utility distribution network to pass to a universal demarcation point. The hybrid cable has a plurality of fiber optic cables and a plurality of copper cables. Fiber optic cables can carry optical signals, and copper cables can carry power. The output port delivers communication services from the general demarcation point to the subscriber's residence. A plurality of modular connectors are fixedly attached to the universal demarcation point. A power supply removably attached to the general purpose demarcation point converts the power to a voltage for energizing the operation of the general purpose demarcation point. A plurality of service modules are plugged into the modular connectors and convert the optical signals sent on the fiber optic cable to a cable suitable for use in the subscriber's residence. The subscriber accessible portion has a port adjacent to the entity accessible portion and which allows the subscriber to test the integrity of the communication service delivered from the utility distribution network. BRIEF DESCRIPTION OF THE FIGURES FIG. 1 is a plan view of a general-purpose demarcation point of the present invention, FIG. 2 is a flowchart showing a path of a communication signal through a general-purpose demarcation point, and FIG. 3 is a flow showing another path of a communication signal through a general-purpose demarcation point. FIG. 4, FIG. 4 is a flow chart showing still another route of a communication signal via a general demarcation point, FIG. 5 is a flow diagram showing still another route of a communication signal via a general demarcation point, FIG. 6 is a control service Module logic flow diagram, FIG. 7 is a flow diagram showing the path of the video signal through the filter module. Detailed description of the preferred embodiment The present invention includes a general demarcation point indicated at 10 in FIG. The universal demarcation point 10 provides an interface between the utility distribution network and the subscriber-owned device to manage the delivery of communication services to the subscriber. The universal demarcation point 10 is particularly suitable for managing the distribution of audio, video and computer data services over fiber optic and copper cables to subscribers in rural areas. The universal demarcation point 10 provides a single interface for delivering audio, video and computer data services to subscribers. As a result, the entity only needs to install one hybrid cable to connect each subscriber to the utility distribution network. Installing a single hybrid cable for each subscriber in a rural area also allows the entity to reduce the costs associated with maintaining several individually installed cables that extend to each subscriber. I do. Due to the costs associated with transmitting electrical signals over long distances to sparsely populated areas, entities serving subscribers in rural areas are constrained in their ability to deliver various communication services to their subscribers. . However, by delivering the various communication services to the subscriber via a single interface, the universal demarcation point 10 provides audio, video and computer data services to a single fiber optic cable or a single Enables transmission over fiber optic cable bundles. Fiber optic cables have greater bandwidth than conventional stranded cables. As a result, fiber optic cables can handle more information than stranded copper or coaxial cables. Because fiber optic cables can handle greater information processing capabilities, more than one type of signal, such as audio and video signals, can be transmitted simultaneously on a single fiber optic cable. Fiber optic cables also do not require the frequent use of amplifiers or repeaters required when communication services are transmitted over stranded copper or coaxial cable. As a result, the transmission of audio, video and computer data services over fiber optic cables allows for improved quality of communication services while reducing the transmission costs of the communication services. Enterprises serving urban areas with higher subscriber densities can cost-effectively increase the benefits of transmitting telecommunications services over fiber optic cables by installing fiber optic cables in the central neighborhood. I found to get. In this regard, communication services are delivered to subscribers using stranded copper or coaxial cable. However, the low population of rural areas makes it impractical to install fiber optic cables either in the subscriber's residence or near the central area. However, universal demarcation now provides a cost-effective mechanism for delivering telecommunications services over fiber optic cables to rural subscribers. The universal demarcation point 10 has a modular form that allows it to be modified to manage the delivery of any type of communication service provided by the entity. This modular form of the universal demarcation point 10 allows this universal demarcation point 10 to be installed with a limited number of components. When a subscriber requests additional services or increases the capital of an entity to provide the ability to provide additional services, the entity may add or modify components, The form of the demarcation point 10 can be easily modified. The general demarcation point is generally divided into an entity accessible portion 12 and a subscriber accessible portion 14. The entity accessible portion 12 includes a motherboard 16. The motherboard 16 has a plurality of connectors 20 for attaching components to the universal demarcation point 10. Preferably, connector 20 is a plurality of modular edgeboard connectors 20. Each of the modular edgeboard connectors 20 is adapted to receive a complementary shaped end of the service module 22. Modular edgeboard connector 20 allows service module 22 to be easily removed from general purpose demarcation point 10 while retaining service module 22 in the desired location at general purpose demarcation point 10. Modular edgeboard connectors 20 having the above properties are available from EDAC Systems (Colmar, PA, USA), Texas Instruments (Houston, TX, USA), and Sullins Electronics (San Marcos, CA, USA). is there. The service module termination, which is complementary to the modular edgeboard connector 20, preferably includes conductive traces. The motherboard 16 also supplies power from the power supply 24 to the modular edgeboard connector 20 so that the modular edgeboard connector 20 can transfer power to the service module 22 that is plugged into the modular edgeboard connector 20. It is desirable to include conductive traces or wires (not shown) for providing The operation of the universal demarcation point 10 is fully powered by power from the utility distribution network. No local power from the subscriber is required to operate any of the components at the universal demarcation point 10. The ability of an entity to provide telephone service without using local power is described in the United States Telecommunications Modernization Plan 58 Fed. Reg. 66, 259 (1993), which is one of the design requirements for a local entity to obtain a loan from the Rural Electrification Administration. The universal demarcation point 10 includes a power supply 24 that is removably attached to the entity accessible portion 12. The power supply 24 converts power from the transmission voltage sent over the utility distribution network to the working voltage required to energize the operation of the general demarcation point 10. Power supplies that convert power at one voltage to power at a different voltage are known. In one preferred embodiment, power supply 24 converts power from a transmission voltage of about -48 volts DC to a working voltage of ± 12 volts DC. Power supply 24 is preferably selected to exhibit a 10 second peak-to-peak surge rating at 400 volts RF (radio frequency) output. The power rating or capacity of the power supply 24 is selected based on the number of service modules 22 used at the universal demarcation point 10. When four service modules 22 are used at the universal demarcation point 10, the power supply 24 is preferably selected with a 250 watt power rating. Power supply 24 plugs into modular edgeboard connector 20 on motherboard 16. Modular edgeboard connector 26 connects power supply 24 to conductive traces or wires (not shown) on motherboard 16 while allowing power supply 24 to be removed from motherboard 16. The entity accessible portion 12 has a fixedly mounted power terminal strip 28. The power terminal plate 28 connects to a copper cable that activates the operation of the general purpose demarcation point 10. Power terminal strip 28 also provides a connection to stranded copper cable when stranded copper cable is used to provide telephone service to the subscriber. For example, an entity may transmit telephone service over stranded copper cable rather than fiber optic cable to reduce the initial cost of installing a universal demarcation point 10. Business entity accessible portion 12 includes an output port 30 and an input port 32. The output port 30 allows the cable carrying the communication service to extend from the universal demarcation point 10 to the subscriber's residence. The input port 32 allows the cable carrying communication services from the utility distribution network to extend to the universal demarcation point 10. The output port 30 and the input port 32 are preferably located on the lower surface 34 or the rear surface 36 of the general purpose demarcation point 10 to minimize problems associated with leakage of material to the general purpose demarcation point 10. The entity accessible portion 12 also desirably includes a fiber optic cable management area 40 located adjacent to the service module 22. Preferably, the fiber optic cable management area 40 has a tray 42 suitable for holding excess or unused portions of fiber optic cable. The fiber optic cable management area 40 thereby helps protect the fiber optic cable from breakage. The universal demarcation point 10 includes a cover (not shown) for the entity accessible portion 12. This cover protects components within the entity accessible portion 12 from damage that can occur from various sources, such as criminal activity or the environment. When the cover is in the closed position, the cover desirably creates a water tight seal with the entity accessible portion 12. Preferably, the cover includes a locking mechanism (not shown) that prevents unauthorized access to components within the entity accessible portion 12. The subscriber accessible portion 14 allows the subscriber to ascertain whether the problem in the communication service is caused by a problem in the utility distribution network or in the subscriber-owned device. Such devices are commonly known as network interface devices. Preferably, the network interface device includes a test port for each communication line entering the subscriber's residence. For example, it is desirable to provide an RJ-11 plug and socket 44 for each telephone line, and it is desirable to provide a coaxial plug and socket 46 for each video line. Other types of devices can be used for the subscriber accessible portion 14 to determine if there is a problem with the utility distribution network or the subscriber owned device. For example, the subscriber accessible portion 14 may include a sensor and an LED (Light Emitting Diode) 48 to indicate whether the communication signal drops below a threshold level. Like the entity accessible portion 12, the subscriber accessible portion 14 includes a cover (not shown) that protects the test port from damage resulting from various causes, such as criminal activity or termination. When the cover is in the closed position, it is desirable that the cover of the subscriber portion create a watertight seal with the subscriber accessible portion 14. The cover of the subscriber portion may also include a locking mechanism (not shown) that prevents unauthorized access to components within the subscriber accessible portion 14. The service module 22 is selected based on the desired communication service that the entity is providing to the subscriber. The modular form of the universal demarc 10 allows the universal demarc 10 to receive analog or digital signals from the utility distribution network and transmit the analog or digital signals to the subscriber residence for use in a subscriber-owned device. And tolerate. The modular form of the universal demarcation point 10 also allows an entity to modify the universal demarcation point 10 to deliver communication services to different types of cables. For example, video signals can be transmitted from the general purpose demarcation point 10 to a subscriber-owned device using a coaxial cable or a fiber optic cable. Preferably, the service module 22 includes an optical receiver service module 22a. The optical receiver service module 22a converts information transmitted as an optical signal over an optical fiber cable into an electrical signal transmitted over a copper cable. To convert the optical signals to electrical signals, the optical receiver service module 22a may include a conventional PIN-FET (positive intrinsic negative negative field effect transistor) photodetector (not shown). desirable. The PIN-FET photodetector produces an electrical signal that varies based on the intensity and wavelength of the light falling on the photodetector. It is desirable that the PIN-FET photodetector has the characteristics shown in Table 1. A preferred PIN-FET photodetector is available from Epitaxx, Inc. (Trenton, NJ, USA) under the name ETX 700. The optical receiver service module 22a also includes a monolithic microwave integrated circuit (MMIC) amplifier (not shown) that amplifies the electrical signal to a radio frequency output of about +6 dBmV. A preferred MMIC amplifier is available from Hewlett Packard (San Jose, Calif., USA) under the designation MAV-11. As those skilled in the art will appreciate, the optical receiver service module 22a may also use known amplifiers for amplifying electrical signals. The optical receiver service module 22a preferably includes a removable physical contact optical connector 72 for connecting the PIN-FET photodetector to a fiber optic cable. This physical contact optical connector 72 is desirable because it provides a low return loss while allowing the optical receiver service module 22a to be quickly disconnected from the fiber optic cable. A preferred physical contact optical connector 72 is available from Siecor (Orlando, Fla., USA) under the name FC-PC. Once the optical receiver service module 22a converts communication services into electrical signals, the electrical signals are separated into individual communication services. The communication services are preferably transmitted in discrete wavelength regions so that the individual communication services can be separated by filtering based on wavelength. When the communication service is transmitted in digital format, other well-known techniques can be used. The optical receiver service module 22a also includes a separate modular connector 64 that provides a connection to a cable that carries individual communication services from the entity accessible portion 12 to the test port 44 of the subscriber accessible portion 14. . For example, when the optical receiver service module 22a delivers a video signal, it is desirable that the optical receiver service module 22a include an SMB connector for connecting to a coaxial cable. To help monitor the condition of the optical signal arriving on the fiber optic cable, the optical receiver service module 22a includes an input signal LED 66 that emits light to indicate when the optical signal has dropped below a threshold. Desirably, the input signal LED 66 emits light when the optical signal drops below -10 dBm. The optical receiver service module 22a also includes a receiver power LED 68 that indicates that the power supply is supplying power within a desired range to energize the operation of the PIN-FET photodetector and the MMIC amplifier. It is desirable that the receiver power LED emit light when the power is about -12 volts. The optical receiver service module 22a is preferably embedded in the outer layer of the metal sheet 70. The metal sheet layer 70 protects components of the optical receiver service module 22a from damage and shields other components at the universal demarcation point 10 from interference by radio frequency radiation. Preferably, the service module 22 also includes an optical transmitter 22b for converting the electrical signal over a fiber optic cable from the general demarcation point 10 to an optical signal transmitted to the entity. The electrical signal is preferably converted to an optical signal using a Fabry-Perot laser (not shown). Due to fluctuations in the electrical signal, the laser changes the current flowing through the light source. This laser is preferably a Fujitsu lightwave semiconductor available under the name FLD130C2PL from Fujitsu America, Inc. (Lake Bluff, Ill.). The optical transmitter service module 22b has a modular connector 78 that connects to a cable that transmits communication services from the subscriber. For example, when the optical transmitter service module 22b delivers a video signal, the optical transmitter service module 22b preferably includes an SMB connector that provides a connection to a coaxial cable. The optical transmitter service module 22b preferably includes the ability to transmit several communication services from the subscriber to the utility distribution network over a single fiber optic cable. To facilitate transmission of two or more communication services over fiber optic cables, it is desirable that the communication services be transmitted at different wavelengths. Like the optical receiver service module 22a, the optical transmitter service module 22b is powered by a power source within a desired range to power operation of components in the optical transmitter service module 22b. It is desirable to include a transmitter power LED 74 indicating that Desirably, transmitter power LED 74 emits light when the power is at about -12 volts. The laser is preferably connected to the fiber optic cable by a removable physical contact optical connector 76. Physical contact optical connector 76 is desirable because it provides a low return loss while allowing the optical transmitter service module 22b to be quickly disconnected from the fiber optic cable. A preferred physical contact optical connector 76 is available from Siecor (Orlando, Fla., USA) under the name FC-PC. The business entity preferably connects the utility distribution network to the universal demarcation point 10 via a hybrid cable 60. Hybrid cable 60 includes a plurality of fiber optic cables and a plurality of copper cables. The number of fiber optic cables and copper cables is selected based on the type of communication service provided by the entity to the subscriber and the number and type of service modules 22 at the general demarcation point 10. When the universal demarcation point 10 is used in a residence, the hybrid cable 60 preferably includes four single mode fiber optic cables and four 16 gauge braided copper cables. Hybrid cable 60 has a protective coating 86 that protects the fiber optic cable and the copper cable from damage. The protective coating 86 is selected based on where the hybrid cable 60 is installed. For example, when the hybrid cable 60 is installed underground, a double layer polyethylene jacket with a single outer layer is suitable for protecting fiber optic and copper cables. A hybrid cable 60 having the above characteristics is available from AT & T Fitell (Carrollton, Georgia, USA). When the hybrid cable 60 includes four fiber optic cables, the first fiber optic cable is preferably used to transmit audio, video and computer data signals to the subscriber, Fiber optic cables are preferably used to transmit audio, video and computer data signals from the subscriber. The third fiber optic cable and the fourth fiber optic cable are spares that can be used to replace a failed fiber optic cable. In an alternative, a third fiber optic cable can be used to provide a high-speed computer data link (greater than 1.5 Mbps) between the subscriber and the entity. When hybrid cable 60 includes four 16-gauge braided copper cables, two of the braided copper cables provide power for operation of components at universal demarcation point 10. The other two braided copper cables are preferably used to provide traditional telephone service to the subscriber. Service module 22 may also include a control service module 22c. The control service module 22 can be programmed using known techniques to perform various tasks at the general demarcation point 10. For example, the control service module 22c can monitor the operation state of another service module 22 and notify the business entity whether or not a problem occurs. When the control service module 22c is used to modify another service module 22, a data path 80 is provided between the service modules. The control service module 22c can also be programmed to actively control the operation of other service modules or other utility meters. For example, the control service module 22c may assign each subscriber a unique identification number similar to a "caller ID". This identification number allows the entity to remotely monitor each subscriber's use of utility services such as natural gas, water and electricity, and then transmit the reading to the entity. By remotely monitoring each subscriber's use of utility services, the entity reduces the costs associated with manually reading utility meters at the subscriber's residence. A remote monitoring system having the above characteristics is described in Brennnan, Jr .; And US Pat. No. 5,243,338 and Venkatara man et al., US Pat. No. 4,862,493. The identification number also allows the business entity to turn off power to the building in the event of a fire or if the subscriber is late for payment for communication services. The control service module 22c also preferably includes the ability to monitor for unauthorized access to the entity accessible portion 12. The control service module 22c not only notifies the entity that the entity accessible portion 12 has been tampered with, but also controls the subscriber to and from the subscriber until the entity resets the general demarcation point 10. It is also desirable to stop all transmissions of the communication service. By stopping all communication service transmissions, the control service module 22c prevents the subscriber from tampering with components within the entity accessible portion 12. Since the universal demarcation point 10 provides a source of entry for all or substantially all utilities into the building, this universal demarcation point provides a central bonding location where all utilities can be grounded. In this way, potential electrical problems arising from incorrect grounding are minimized. The modular structure of the universal demarcation point 10 allows the general purpose demarcation point 10 to operate in various forms. Once the universal demarcation point 10 is attached to the subscriber's residence, the generic demarcation point 10 provides the entity with additional subscriber communication services that cannot be performed without already accessing the subscriber's residence. Make it possible. In the flow diagrams that follow, each component is generally identified as being within the boundaries of the general demarcation point 10. Those skilled in the art will appreciate that the placement of components in a particular service module 22 is a design choice based on the size of the service module 22 and the desired functionality of the service module 22. The universal demarcation point 10 transmits audio, video and data signals from the utility distribution network over fiber optic cables and to the utility distribution network over another single fiber optic cable, as shown in FIG. Enable. The incoming optical signal is converted to an electrical signal by an optical receiver. After being converted to electrical signals, the electrical signals are audio, video, and computer data signals that are separated based on differences in the wavelength at which the signals are sent. The separated audio, video and computer data signals are sent to an audio, video and computer data output processor, respectively. This audio, video and computer data output processor converts the signal into a form usable by the subscriber. For example, audio signals are transmitted to the subscriber's residence using stranded copper cable having RJ-11 connectors, and computer data signals are transmitted to the subscriber's residence using either the RS232 or RS485 protocol. It is desirable to be done. This preferred embodiment of the universal demarcation also includes the ability to transmit audio, video and computer data signals from the subscriber. Separate incoming audio, video and computer data electrical signals are first multiplexed onto a single copper cable based on the different wavelengths over which the signals are transmitted. The electrical signal is then transmitted using a copper cable to an optical transmitter, where the electrical signal is converted to an optical signal that is sent through a utility distribution network of fiber optic cables. In this preferred embodiment, the operation of each component is preferably monitored by the control service module. When the control service module detects that one of the components has an error, the control sends an error message to the entity. This error message is multiplexed with audio, video and computer data signals for transmission over a fiber optic cable utility distribution network. The universal demarcation point of the present invention also allows incoming and outgoing audio, video and computer data signals to be transmitted over a single fiber optic cable as shown in FIG. In such an embodiment, the optical signal from the utility distribution network is preferably separated from the optical signal transmitted to the utility distribution network using a conventional multiplexer. A conventional multiplexer is preferably obtained from JDS Fital (Ontario, Ottawa, Canada) under the name WD-1315X. The incoming optical signal is then processed in the same manner as described for the embodiment shown in FIG. After the outgoing audio, video, and computer data signals have been converted to optical signals as described above with respect to the embodiment shown in FIG. 2, the optical signals are transmitted using a conventional multiplexer. Is transmitted to the utility distribution network by combining with the incoming optical signal. Also, as in the embodiment shown in FIG. 2, the operation of each component in this embodiment is monitored by the control service module. In yet another embodiment of the universal demarcation point of the present invention shown in FIG. 4, incoming audio and video signals are routed from a utility distribution network onto a first fiber optic cable. The embodiment includes a decoder for decoding a communication service from a digital signal. Outgoing audio and video signals are sent from the subscriber onto a second fiber optic cable. The embodiment also includes an encoder that encodes the communication service into a digital signal. The embodiment also shows that both outgoing and incoming computer data is transmitted and received over a third fiber optic cable. By using a separate fiber optic cable to send and receive only computer data signals, this embodiment is more efficient than when computer data signals are combined with audio or video signals on a single fiber optic cable. Also allows computer data transfer to occur at higher speeds. Yet another embodiment of the universal demarcation point of the present invention is shown in FIG. This embodiment shows a general demarcation point for receiving video and data signals over fiber optic cables. The optical receiver converts an optical signal into an electric signal. This electrical signal is then separated into individual video and data signals that can be transmitted to the subscriber residence using a conventional cable, such as a stranded copper conductor or coaxial cable. To reduce the cost of creating a universal demarc with optical transmitters and receivers, the universal demarc receives the audio signal over a stranded copper cable. However, the modular structure of the universal demarc allows the entity to later extend the universal demarc to include incoming and outgoing audio signals on fiber optic cables. The operating status of the components at the general demarcation point is monitored by the control service module indicated at 22c in FIG. The logic according to one embodiment of the control service module is shown in FIG. The control service module initiates each cycle by detecting whether the power supply is providing power within a specified operating range. If the power is not within this operating range, the control service module sends an error message to the entity indicating the error. The control service module then monitors the operation of the optical receiver, decoder, video output device, data output device, and audio transmission level. If these values are not satisfactory, the control service module transmits a corresponding error message to the entity. The monitoring process is continuously repeated while the universal demarcation point remains connected to the utility distribution network. The general demarcation point may also include a filter module as shown in FIG. The filter module allows the entity to control the channels that the subscriber can see. The filter module allows the entity to send unscrambled video signals to the utility distribution network. By sending unscrambled video signals over the utility distribution network, an entity can provide subscribers with higher quality video signals. There is no need for the entity to send out the scrambled video signal because the video signal is sent from a utility distribution network of fiber optic cables, which is difficult for a fraudulent user to tap into. Before entering the filter module, it is desirable that the video signal be split into two lines (lines 1, 2). Line 1 is passed through filter 1 where the video signal is filtered such that only the off-air video signal remains on line 1. Alternatively, the off-air video signal can be obtained from another source, such as an antenna or a satellite antenna (dish). Line 2 is passed to a filter module where the video signal is filtered to produce a video signal that the entity restricts access to based on the service paid by the subscriber. By restricting access to certain services, an entity can charge subscribers additional fees to receive services. The line 2 is desirably divided into a plurality of lines. Each line is filtered such that only the desired portion of the video signal remains on the line. After each video signal has been filtered, each video signal passes through a controller. The controller passes or blocks the video signal based on whether the subscriber has paid for the desired channel. For example, a video signal can be split into basic cable television service, premium channels, and pay-per-view channels. The operation of each controller is controlled by a control signal (line 4) from the control service module. This control signal passes through the master controller, where the control signal is directed to the appropriate controller. The master controller also controls the off-air video signal line (shown) so that a portion of the off-air video signal is blocked when the subscriber is receiving a premium channel or a pay-per-view channel. A signal can also be sent to the controller in (1). By sending more than one video signal to each channel, an entity can increase its ability to provide more programming to a subscriber within a given bandwidth. Preferably, said filter module also includes system service video and audio signals (line 6). Line 6 indicates that system services are located on a single cable, but those skilled in the art will appreciate that individual cables can be used to carry audio and video signals. As the audio and video signals are transmitted on individual cables, it is desirable that a conventional multiplexer be included on the cable to allow each signal to be transmitted to an RF modulator. As shown in FIG. 7, the RF modulator preferably produces a signal that can be viewed on channel 3 by the subscriber. After the system service signal passes through the RF modulator, the system service signal passes through a controller. Like other controllers, this controller is controlled by signals from the control service module sent to the controller via the master controller. Preferably, each video signal is combined on a single cable before being sent out of the filter module. After merging into a single cable, it is desirable to amplify the video signal using a conventional amplifier. Conventional amplifiers return the video signal to the level required for use by the subscriber. After the video signal exits the filter module, it is combined with the off-air video signal onto a single cable (line 8). Placing all video signals on a single cable allows a subscriber to plug a single cable into a subscriber-owned device to obtain all video services. Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification code FI H04B 10/14 H04B 9/00 C H04L 12/02 H04M 19/08 H04N 7/10 (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FR, GB, GR, IE, IT, LU, MC, NL, PT, SE), OA (BF, BJ, CF, CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, LS, MW, SD, SZ, UG), AM, AT, AU, BB, BG, BR, BY, CA, CH, CN, CZ, DE, DK, EE, ES, FI, GB, GE, HU, JP, KE, KG, KP, KR, KZ, LK, LR, LT, LU, LV, MD, MG, MN, MW, X, NO, NZ, PL, PT, RO, RU, SD, SE, SI, SK, TJ, TT, UA, US, UZ, VN (72) Inventor Mead, Craig Dee 13042, New York, United States Cleave Land, Center Street 753

Claims (1)

[Claims] 1. Interface between the utility distribution network and the subscriber-owned equipment Provides a general-purpose component that manages the delivery of communications services to subscribers. At the border,       Transmits multiple optical fiber cables and power capable of transmitting optical signals Via a hybrid cable having multiple copper cables For delivering outgoing communication services from the utility distribution network An input port at the general demarcation point,       Output at a universal demarcation point for delivering communication services to subscriber residences Port and       Multiple modular connectors fixedly attached to a general demarcation point,       Converts power to a voltage that activates the operation of a general demarc, removes it to a general demarc A freely mounted power supply,       Fiber optic cable to a cable suitable for use in the subscriber's residence. Multiple services that can be plugged into modular connectors Module   An entity accessible part;   Adjacent to the entity accessible part and subscribed by the utility distribution network Network that allows you to test the integrity of the Subscriber-accessible part with General demarcation point with. 2. Removably attached to the general demarcation point in the business accessible part Further comprising a motherboard, wherein the plurality of modular connectors are connected to the motherboard. Mounted on the motherboard, and the motherboard has a plurality of conductive Traces, wherein said conductive traces transfer power from a power supply to a service module The universal demarcation point of claim 1, wherein the demarcation point can be transmitted. 3. A contract wherein the plurality of service modules includes a video service module. The universal demarcation point according to claim 1. 4. The video service module converts an optical signal to an electrical signal and The universal demarcation point of claim 3, including a receiver for transmitting air signals to a coaxial cable. 5. The video service module converts an electrical signal to an optical signal and 5. The universal demarc as claimed in claim 4, including a transmitter for transmitting the signal over an optical fiber cable. . 6. The video service module further includes a multiplexer; A plexer is an optical signal transmitted by the transmitter and received by the receiver. General demarcation point according to claim 5, which allows the signal to be sent to a single optical fiber cable. . 7. The plurality of service modules include an audio service module. The universal demarcation point according to claim 1 including: 8. The audio service module converts an optical signal to an electrical signal; The universal demarcation of claim 7, including a receiver for transmitting the electrical signal over a stranded copper cable. point. 9. The audio service module converts an electrical signal to an optical signal; 9. The general purpose of claim 8, further comprising a transmitter for transmitting said electrical signal to a fiber optic cable. Demarcation point. 10. The audio service module further includes a multiplexer; A multiplexer is sent by the transmitter and received by the receiver 10. The universal of claim 9, wherein the optical signal can be sent over a single optical fiber cable. Demarcation point. 11. The plurality of service modules comprises a computer data service module. The universal demarcation point according to claim 1, comprising joules. 12. The computer data service module converts an optical signal to an electrical signal. And a receiver for converting the electrical signal to a computer cable. Item 12. The general demarcation point according to item 11. 13. The computer data service module converts an electrical signal to an optical signal And a transmitter for converting said optical signal to an optical fiber cable. 2. General demarcation point described in 2. 14． The computer data service module further comprises a multiplexer Wherein the multiplexer is transmitted by the transmitter and transmitted by the receiver. 2. The method of claim 1 wherein the received optical signal is transmitted over a single fiber optic cable. General purpose demarcation point described in 3. 15. Claims wherein the plurality of service modules include a control service module Item 1. The general demarcation point according to item 1. 16. The control service module receives a signal from the utility meter. Use of utility services received and passed through the utility meter A universal demarcation point according to claim 15, comprising a receiver for monitoring. 17． The control service module further transmits a signal to the utility manufacturer. To the utility service via the utility meter 17. A universal demarcation point according to claim 16, including a transmitter for controlling the demarcation. 18. Each of the service modules includes a monitoring port, and each of the monitoring ports The universal demarcation point of claim 15, wherein each sends a signal to a control service module. 19. Receiving the control service module receiving a signal from the monitoring port And a transmitter for transmitting the signal to the fiber optic cable. General purpose demarcation point described in 8. 20. All utility services delivered via the generic demarcation point The universal demarcation point of claim 15, further comprising a grounding terminal that provides a central grounding. 21. The plurality of service modules include a filter module, wherein the filter Luta module       A plurality of parts for separating each part of the electric signal from the video service module Filter and       Block portions of the electrical signal from being transmitted to the subscriber-owned device The filter associated with each filter in communication with the control service module. Number of controllers and 19. The universal demarcation point of claim 18, comprising: