WO1996006484A2 - Information communication systems - Google Patents

Abstract

A system for distributing electronic information signals throughout a structure, particularly a residential dwelling, is disclosed. The disclosed apparatus also adapts a plurality of electronic information signals to be received by one or more information utilizing devices which are located throughout a structure. In accordance with particular aspects of the present invention, an improved structure and method of installing a plurality of communication cables (80) in a wall adjacent to an existing electrical box (252) attached to a building member (16) is disclosed. The system allows home theater components to be easily and properly set up or changed.

Description

INFORMATION COMMUNICATION SYSTEMS

BACKGROUND 1. The Field of the Invention.

This invention relates to apparatus and methods for distributing electronic information signals in a structure . 2. The Prior Art . For most of civilization's recorded existence, information has traveled from person to person via face- to-face communication or via tangible documents. With the introduction of the telegraph and the telephone the transmission of information became faster. With the later introduction of broadcasting, the transmission of the same information to vast numbers of people became almost immediate.

The concept of broadcasting has dominated information transfer during the twentieth century. Throughout the century, the customary approach in the information dissemination industry has been to distribute the largest possible quantity of identical information to as many locations as possible. In contrast to the customary wisdom in broadcasting industry, the promise of the new information transfer technologies is allowing point-to-point transmission of only the information which the recipient desires to receive.

The explosive growth and progress made in digital electronics, and particularly the popularization of the general purpose microprocessor, has propelled the information revolution now being experienced in industrialized societies. Along with the promise of delivering massive amounts of customized information to a recipient, has come the challenge of providing transmission media which can furnish the immense amount of spectrum bandwidth necessary to accommodate the digital information carrying such information.

While numerous parties have solutions for providing the broad bandwidth necessary for getting the necessary digital information to a curbside location, relatively little attention has been given to distributing the digital information inside of the building at the end user's location, particularly residential dwellings. Until most recently, a twisted pair of wires carrying a bandwidth limited telephone signal, and in some cases a coaxial cable carrying television signals, was considered all the information transfer media which could be desired in a structure. With recent developments, an explosion in the amount of information which is delivered to a residential or commercial location is about to occur. References to an "information super highway" are raising the expectation that every member of a modern industrialized society will soon have access to vast amounts of information for education, business, and entertainment. Moreover, the promise is being made that this information will be delivered to both commercial and residential locations in an easy-to-use format. Unfortunately, the promise of the information super highway has the potential of becoming another unused complicated piece of technology, particularly for the residential customer. While not recognized generally in the industry as a problem, each of the utility companies, including electric power service providers, telephone service providers, and cable television service providers, are all promising and vying to be the provider of the medium which will convey the information super highway to the multitude of residential and business customers. In order to accommodate the bandwidth needed to carrying the data on the information super highway, utility companies are proposing to devote enormous resources to installing fiber optic media, or other wide bandwidth media, to each structure within its service area.

Disadvantageously, each of the utility companies is developing and proposing proprietary protocols and hardware. Unfortunately, each of the proprietary protocols are (purposefully in some cases) not compatible with the other protocols. Some utility companies hope that their protocol can become the "standard" for the industry and thus control the market. For example, once the medium is selected, whether fiber optic cable, coaxial cable, or a microwave radio frequency link, the common understanding is that each utility company will provide a "box," i.e., hardware, which will receive the information signals conveyed on their particular medium and will process the information signals in whatever way is necessary to make it useful to the customer. Unfortunately, the outlook for the customer is that there will be a multitude of "boxes" installed within each residential or commercial structure. It appears that, for example, the local electric power provider may require a box which will interact with a television while the local cable television provider may require a PC compatible computer and Windows'" based programs with the local telephone service provider requiring the purchase of a new "smart telephone." As a further example of a utility provider is a direct satellite broadcast subscription service which requires the lease or purchase of a box for each television or device used to access the service.

In order to gain access to the information super highway, subscription to one or more of the utility company providers will be necessary in the future. Disadvantageously, under the proposed schemes, every location at which access is desired, for example in a kitchen, bedroom, den, and entertainment room in a residential structure, will require a box at each lpcation. In other words, access at multiple points in a structure will require the purchase or rental of several boxes. With recent developments, there is an ever increasing need and demand to have the home, as well as the business, accommodate information transfer media which is necessary to provide for entertainment, education, and business purposes. Unfortunately, those in the industry proposing to distribute information to the home have not considered the problem of, much less proposed viable solutions to, the problem of how to move the information from one point to another within the home or other structure. This problem is exacerbated by the number of existing homes and buildings which require retrofitting to allow transfer of information to whichever room in the home or structure is desired. Another problem which has not been recognized in the art is equipping a residential dwelling or other structure for accommodation of future expansion using technologies which have not yet been developed. Examples of technologies which are now becoming commonplace, but which were not even contemplated in prior decades, include High Definition Television (HDTV) , networked data and communications devices, home automation systems, smart appliances, direct broadcast satellite systems, home theater systems, interactive television, and fiber optic information transfer systems.

One trend which was not considered when many homes were constructed was the increasing number of persons working in their homes rather than enduring a daily commute to an office. Thus, many persons are demanding not only a home information distribution system which can convey existing electronic information signals to and from any of the many different rooms in the home but a home distribution system which can also accommodate electronic information signals which may be used in the future.

The current state-of-the-art does not solve the above-mentioned problems. All of these drawbacks found in the current state-of-the-art, and more drawbacks which will be appreciated shortly, hinder consumers of information from realizing the full benefits of the information revolution. BRIEF SUMMARY OF THE INVENTION In accordance with one aspect of the present invention, an improved method and structure for installing a plurality of communication cables in a wall adjacent to an existing electrical box attached to a building member is provided. The improved method and structures preferably include a template for cutting a properly sized hole in the wall, a mounting frame which is inserted into the hole and attaches to the wall, and a capture plate configured for holding a plurality of connectors attached to respective communication cables. The method provides that the communications cables are positioned inside of the wall away from potential harm during the installation of wall board. A cover plate conceals the capture plate and mounting frame and provides a more satisfactory installation of the communication cables.

In order to install multi-line telephone system wiring, but readily adapt it for use with a single telephone line, another aspect of the present invention adapts a multi-line telephone signal distribution hub for use with a single telephone line, or two telephone lines. The apparatus preferably connects the jacks provided on the telephone signal distribution hub in parallel with each other which allows the wiring for an internal KSU/PBX telephone system to be installed and a single telephone line to be readily interfaced with the multi-line wiring of the telephone signal distribution hub. A KSU/PBX telephone system control box and additional telephone lines from the telephone service utility can be readily connected at a later date.

In accordance with another particular aspect of the present invention, a system for distributing audio signals from a central location to a plurality of discrete zones contained within a structure, such as a residential dwelling, is also provided. The system allows changes to be readily and conveniently made in the distribution of audio signals by making the necessary signals available in a single location and providing that all of the connections which are made by a user, for example a homeowner, are accessible from the front of the apparatus, rather than requiring access to the rear of equipment, and by providing readily understandable visual notation on the apparatus.

Another aspect of the present invention greatly simplifies the setting up and operation of home theater installations in a room equipped with four, five, six, or more, speaker connection locations. The apparatus of the present invention allows home theater components to be easily and properly set up or changed.

In accordance with another aspect of the present invention, a system for distributing electronic information signals throughout a structure, particularly a residential dwelling, is provided. The structure includes a plurality of enclosures or rooms between which the signals are conveyed to a node zero location. The system distributes both signals which originate outside of the structure, namely, telephone signals, community cable television signals, and signals which originate within the structure, namely, from computer networks, home automation systems, lighting control systems, and audio/video signals.

In accordance with particular aspects of the present invention, signal carrying buses, which each preferably include at least one twisted pair cable, at least one coaxial cable, and at least one optical fiber, extend between the node zero location and each of the pertinent rooms. At the node zero location, dissemination means is provided for selectively conveying any electronic information present at the node zero location to any of the buses leading to the rooms of the structure. The information signals conveyed by the signal buses can be broadcast or received via infrared or radio frequency devices which are interfaced to the apparatus of the present invention and which may be positioned at the node zero location or at other locations along the signal buses in the structure.

In accordance with yet another aspect of the present invention, an apparatus is provided for presenting electronic information signals from a plurality of electronic information carrying conductors to devices in a room which utilize the information. The apparatus includes a plate with means for releasably attaching the mounting plate to an existing electrical box installed in a wall. A plurality of apertures are provided in the plate and mounted in the apertures are one or more of the following: an AC wiring device, coaxial cable connector, an optical fiber connector, and a twisted pair cable connector. A mounting frame also is provided with means for attaching the mounting frame to the exterior side of an electrical box installed in the wall . The mounting frame is fabricated with an open back so that cables can pass freely therethrough and the cables attached to connectors which are selectively installed in each of the plurality of apertures on the plate. With the mounting frame attached to the electrical box, the plate is secured to the electrical box and to the mounting frame so that the plate forms a cover for both the electrical box and the mounting frame so that the plate is substantially flush on the surface of the wall. The information conveyed by the cables from node zero location is presented to the connectors installed on the plate so that the information is accessible to devices within the room.

Pursuant to yet another aspect of the present invention, an apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices which are located throughout a structure, such as a residential structure or commercial structure, is provided. In accordance with the present invention, a plurality of first input means for receiving each of a plurality of information signals are provided. The information signals may be of the type which are provided by utility services such as the telephone service provider, the electric power service provider, and the cable television service provider. Each of the utility service providers conveys electronic information signals which comply with their own inherent protocol conventionally requiring dedicated hardware and software for recognition or decoding at the residential or commercial structure. Means for converting the each of the input signals from their inherent protocol to a common protocol is provided. A means for directing all of the common protocol signals to the information utilizing devices, (for example, televisions, computers, smart appliances, and others) located within the structure is also provided. Thus, all of the information utilizing devices need only recognize information signals complying with one common protocol rather than recognize each of the different protocols which would be encountered if the electronic information signals were distributed unconverted from the medium of the utility service provider.

In keeping with another aspect of the present invention, an apparatus is provided and configured to handle analog information signals and digital information signals provided by a utility service provider and signals generated within the structure such as signals generated by satellite television decoders and other signal generating devices. The apparatus of the invention is preferably modular allowing for easy expansion. The apparatus can receive signals conveyed via fiber optic cable, coaxial cable, and twisted pair cable. The apparatus is preferably software driven and preferably includes one or more digital signal processors and a microprocessor. The processors can be programmed at the node zero location or from a remote location, such as a utility service provider central office. The apparatus can be programmed by the utility provider to only allow the customer access to certain information signals and also programmed by the customer to provide the features desired. The programmability of the apparatus allows the apparatus to readily accommodate numerous different protocols and can be adapted to many different applications as the need arises.

BRIEF DESCRIPTION OF THE DRAWINGS In order to better appreciate how the above-recited and other advantages and objects of the invention are obtained, a more particular description of the invention briefly described above will be rendered by reference to specific embodiments thereof which are represented in the accompanying drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:

Figure 1 is a diagrammatic representation of the prior art .

Figures 2A and 2B together provide a diagrammatic representation of a first embodiment of the present invention.

Figure 3 is a perspective view of a portion of the first embodiment represented in Figures 2A&B.

Figure 4 is a front plan view of the first embodiment represented in Figure 3. Figure 4A is back plan view of the first embodiment represented in Figure 4.

Figure 4B is an interior plan view of back side of the cabinet illustrated in Figure 3.

Figure 4C is a perspective view of another embodiment of the present invention.

Figure 5 is a front elevational view of a portion of a second embodiment of the present invention. Figure 6 is a perspective view of a cable connection holder preferably included in the second embodiment of the present invention.

Figure 6A is an exploded perspective view of the structures represented in Figures 5 and 6.

Figure 6B shows another cable connection holder structure of the present invention.

Figure 6C illustrates a cover plate structure used in the cable connection holder structure represented in Figure 6B.

Figures 6D and 6E are front and side views, respectively, of a capture plate structure used in the cable connection holder structure represented in Figure 6B. Figure 6F shows the installation of a mounting plate in a wall with the capture plate and cover plate attached thereto.

Figure 6G shows the structures represented in Figure 6F in a reversed orientation. Figures 6H-I provide plan views additional arrangements for the cover plate.

Figure 7 is a functional block diagram of another embodiment of the present invention which functions as an interface for electronic information signals. Figure 8 is a functional block diagram of yet another embodiment of the present invention which functions as an interface for electronic information signals .

Figures 9-9A are diagrammatic and schematic, respectively, views of a telephone connection adapter in accordance with another aspect of the present invention.

Figure 10 is a diagrammatic view of an audio signal distribution system in accordance with another aspect of the present invention. Figures 11A-C are views of a home theater signal collection and distribution system. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made to the drawings wherein like structures will be provided with like reference designations . In accordance with one aspect of the present invention, described herein is an electronic information distribution system, which also is generally referred to as a "network" in the industry, which is flexible and which can be adapted for future technologies. It is to be understood that the terms "electronic information" and "electronic information signals," as used herein, are intended to refer to any information which is carried by a conductor such as a conductor of electricity or a conductor a light, e.g., an optical fiber. Such information signals can also be carried over modulated radio frequency and infrared broadcast transmissions in accordance with the present invention.

Figure 1 provides a representation of a modern information distribution system present in a residential dwelling using previously available schemes. The information distribution system represented in Figure 1 is typical of the most advanced available technology prior to the present invention. The hallmark of such a prior art arrangement is the haphazard myriad of cables and connectors which are required to distribute the information carrying signals. Because of the difficulty of installing such a prior art arrangement, only those cables and components which are essential to the required functions are installed; installing additional cables and devices which are not required at the present to carry out the functions required at the time would add to the confusion and difficulty of the installation. Figure 1 shows a portion of a utility room with nearly an entire wall, generally designated at 10, in the room being devoted to distributing information signals to just the rooms in the residential dwelling which currently require such signals; no accommodation for future needs has been made. Represented generally at 12 in Figure 1 is an arbitrary arrangement of coaxial cables and devices which are capable of conveying television signals into rooms to which coaxial cables have been strung.

Also represented generally at 14 in Figure 1 is a plurality of twisted pair cables which are used to convey telephone signals which arrive on one of the four telephone lines coming into the house to those rooms already provided with the necessary telephone connectors. The signals which the twisted pair cables convey also commonly include doorbell signals, telephone signals to a number of rooms, and thermostat signals to the heating and cooling system. Nowhere in the arrangement represented in Figure 1 is accommodation made for distributing bidirectional wide band information signals to the rooms of the home.

Reference will next be made to both Figures 2A and 2B which together provide a diagrammatic representation of a first embodiment of the present invention.

Depicted in Figures 2A&B is a man-made structure which is represented by the box 102. The structure preferably represents a residential dwelling structure, such as commonly referred to as a "home" or a "house." The structure 102 can also preferably be a commercial structure, such as an office building or an industrial facility. Furthermore, the term "structure," as used herein, may also include a man-made edifices which are not contiguous, such as a number of individual buildings which are separated by large distances. The present invention, however, provides the greatest benefits in when applied in a residential dwelling structure due to the traditional construction techniques and customs in the industry. Significantly, not only has the industry not answered the problems which the present invention solves but the industry has not wholly recognized such problems. The invention described herein can be used with many other advantageous devices and systems . For example, the system described in U.S. Patent Application No. 08/326,684 entitled Automated Appliance System, which is now incorporated herein by reference in its entirety, describes a system which may be used in cooperation with the present invention. U.S. Patent Application Nos. 08/290,230 (entitled Electronic Information Distribution System) and 08/301,910 (entitled Electronic Information Interface) also provide useful information and are now all incorporated herein by reference in their entireties.

Represented diagrammatically in Figures 2A&B are twelve enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) which preferably represent rooms which are commonly found in a residential dwelling. Alternatively, the rooms (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) may represent areas or rooms in a commercial structure or other man-made edifice.

One preferred embodiment of the electronic information distribution apparatus of the present invention is generally represented at 100 in Figures 2A&B. The apparatus is commonly referred to in the art as the "node zero" since all signals entering or leaving at other nodes on the information distribution system are routed through the apparatus 100. The apparatus 100 conveniently and flexibly provides that information signals can be routed or disseminated from the apparatus 100 to any of the enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) . The apparatus 100 receives information signals from any of a number of external and internal sources which may be presently available or which may become available in the future and distributes such information wherever desired in the structure. Represented in Figures 2A&B is a junction box 104 which receives information signals from an external source. The external source may be characterized as a source of, for example, telephone signals, cable television signals, satellite broadcast reception signals, and antenna reception signals. While it is currently common to convey cable television signals via coaxial cables, and to convey telephone signals up to the junction box 104 via twisted pair cables, the present invention provides the great advantage of accommodating such information signals regardless of the media used to convey such signals. It is also advantageously within the scope of the present invention to convey information signals in both "upstream" and "downstream" directions, either on a single cable or on two or more cables. Thus, the apparatus 100 can receive and redistribute information received from any number of devices positioned throughout the structure 102.

In Figures 2A&B, three cables 106, 108, and 110 are illustrated connecting the junction box 104 to a signal processor 172. Cable 110 preferably comprises twisted pair cables as customarily used to convey telephone signals. Cable 108 is preferably a coaxial cable as is customarily used to convey television signals and other radio frequency signals. Cable 106 is preferably a sheathed optical fiber cable which is generally not currently used to convey information signals in a residential dwelling but, due to its capacity to accommodate a band width which is greater than that provided by coaxial cable and much greater than that provided by a plurality of twisted pairs cables, is advantageously included in the present invention.

It will be appreciated that the inclusion of optical fiber cables in the system of the present invention, as will be explained in more detail shortly, allows the system to convey a virtually unlimited amount of information, even much more than could be conveyed via a coaxial cable or twisted pair cables. Furthermore, the signal processor 172 can be devised to combine, modulate, and condition (using digital or analog techniques) any signals which enter the structure 102 via the junction box 104 or signals which originate within the structure, for example, a computer network or video disk player. Alternatively, the signal processor 172 can be devised to route signals using passive signal splitting techniques within the scope of the present invention. Thus, the system has the advantage of taking whatever information which is presented to at the junction box 104 and disseminating the information to one or more of any of the enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) . Moreover, the system can also gather and disseminate information signals generated within the structure 102 as will understood from the information set forth herein.

In the preferred embodiment represented in Figures 2A&B the telephone signals which are input to the signal processor 172 are output to a set of twisted pair connectors represented generally at 116 via twisted pair cable 110A. The twisted pair connectors 116 (116A-I) are preferably eight (8) conductor female connectors which comply with the EIA/TIA (Electronics Industry Association/Telecommunications Industry Association) standard promulgated in the Technical Systems Bulletin (TSB) 36 as Category 5 and referred to in the industry as "CAT5." The EIA/TIA TSB 36 is now incorporated herein by reference. It will be appreciated that the

CAT5 standard requires that the connectors 116, wires attached to the connectors 116, and other characteristics of the media meet criteria which conventional wisdom treats as superfluous for conveying telephone signals. In contrast to conventional wisdom, the present invention incorporates twisted pair cables which provide far better transmission characteristics than called for by conventional wisdom in the residential dwelling industry. The described connectors, as with all the connectors described in connection with the present apparatus, are commercially available devices which preferably snap into apertures formed in a front panel 142 to allow for convenient fabrication of the apparatus 100.

Still referring to Figures 2A&B, television signals which are input to the signal processor 172 are output to a plurality of coaxial cable connectors represented generally at 114 (114A-L) via a coaxial cable 108A. The coaxial cable connectors 114 are preferably those which comply with the known industry standard referred as "RG6." The plurality of coaxial cable connectors 114 are interconnected to send signals downstream to other devices which are located in each of the enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) .

Also represented in the preferred embodiment of Figures 2A&B are a plurality of fiber optic connectors generally represented at 112 (112A-G) and 113 (113A-G) . The fiber optic connectors 112 are those which preferably send signals downstream to other devices. The fiber optic connectors 113 are those which preferably receive signals which are sent by other devices in the structure 102 and convey those signals to the node zero. It will be appreciated that the bandwidth of optical fiber cable is great enough to allow optical fibers, or in some cases only a single optical fiber, to convey all of the information signals which may be desired in the structure using appropriate modulation techniques in the signal processor 172 and demodulation techniques at each enclosure (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) . The optical fiber connectors 112 and 113, as well as all of the optical fiber connectors described herein are preferably those available in the industry and known as "ST" style connectors, although other connectors, such as those known in the industry as "SC, " "SM, " "FSD," "RSD," & "MM" styles can also be used within the scope of the present invention. The optical fiber connectors 113 communicate with the signal processor 172 via fiber 106A. Also represented in Figure 2 is a set of twisted pair, coaxial, and fiber connectors 117A-F which connected to the signal processor 172 via connection 106A and which can carry out many functions but which are particularly adapted to provide a connection to media provided by a utility company such as an electric utility, gas utility, telephone, cable television or other utility provider.

Between each enclosure (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) and the apparatus 100 there is strung a bus preferably comprising two optical fibers, two coaxial cables, and two twisted pair cables. Exemplary of the bus which is strung between the apparatus 100 and each of the enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) is that which is detailed between a first set of connectors, represented generally at 118, and a first enclosure 148. Each of the enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, - 168, and 170) preferably represent rooms in a residential dwelling such as a home office, bed rooms, home theater, family room, and kitchen.

As represented in Figures 2A&B, two twisted pair cables 178A and 178F are strung from the first enclosure 148 and are individually connected to twisted pair connectors 118A and 118F, respectively. The twisted pair cables 178A and 178F and the corresponding connectors 118A and 118F preferably comply with the CAT5 standard described earlier. Two optical fibers are also strung from the first enclosure 148 and are individually connected to fiber optic connectors 118B and 118E, respectively. Two coaxial cables 117C and 117D are also strung from the first enclosure 148 and are individually connected to coaxial cable connectors 118C and 118D, respectively. The coaxial cables 117C and 117D and the corresponding connectors 118C and 118D preferably comply with the RG6 standard as described earlier. The twisted pair cables 117A and 117F, the optical fiber cables 117B and 117E, and the coaxial cables 117C and 117D collectively form a set of information conveying media and are referred to herein as a "bus." Each set of media which is strung between the enclosures (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, and 170) and the apparatus 100 preferably follows the same pattern as was just described in connection with bus 178. Thus, rather than the detail of the connections being represented, only the bus between each enclosure (comprising cables A-F) and the set of connectors on the apparatus 100 is represented in the case of the remaining enclosures.

The bus connection between each of the enclosures and the sets of connectors on the apparatus 100 are set forth in Table A. It will be appreciated that the information set forth in Table A is merely exemplary and many other arrangements of the present invention can be devised by those skilled in the art using the information set forth herein.

TABLE A

Enclosure Bus Set of Connectors

148 178 (A-F) 118 Enclosure Bus Set of Connectors

150 180 (A-F) 120

152 182 (A-F) 122

154 184 (A-F) 124

156 186 (A-F) 126

158 188 (A-F) 128

160 190 (A-F) 130

162 192 (A-F) 132

164 194 (A-F) 134 Enclosure Bus Set of Connectors

166 196 (A-F) 136

168 198 (A-F) 138

170 200 (A-F) 140

Reference will next be made to Figure 3 which is a perspective view of the apparatus 100 which has been installed in a cabinet, or other housing, which includes the front panel 142, a side panel 144, and a top panel 146, to conveniently function as one available means for supporting the other components of the apparatus. By comparing the prior art approach represented in Figure 1 to the apparatus 100 of the present invention represented in Figure 3, the advantages of simplicity, reliability, reduced cost, and compactness provided by the present invention will be appreciated. The housing for the apparatus can be mounted on a wall, sit on a floor, or placed in another suitable location.

It is also preferred that the sets of connectors (118, 120, 122, 124, 126, 128, 130, 132, 134, 136, 138, and 140) each be color coded for ease of use. For example, the connectors in each vertical column of connectors illustrated in Figure 3 can have a particular color associated therewith. Moreover, each set of connectors (118, 120, 122, 124, 126, 128, 130, 132, 134, 136, 138, and 140) is divided into two groups, with each group including three connectors. One group of three connectors is preferably referred to as "Interactive A" with the other group of three connectors preferably referred to as "Interactive B" indicating their potential function. Such color coding and references further improve the convenience and utility of the embodiments of the present invention. This is in contrast to the haphazard and confusing arrangements which are often found in the prior art which are not only difficult to install but which are complex and perplexing to trouble shoot when problems arise and to modify when changes are necessary.

Also represented in Figure 3 is a telephone system control box 173, such as those which are available in the art, which can be integrated into the apparatus using the information set forth herein. The telephone system integrated into the apparatus 100 can be any one of a number of telephone systems available in the industry. The apparatus of the present invention can accommodate old style telephone systems as well as the modern digital and analog telephone systems. Moreover, it will be appreciated by those skilled in the art that an intruder detection system, i.e., a building alarm system, as is available in the art, can also be readily integrated into the apparatus of the present invention. Still further, automated lighting control systems, intercom systems, and home automation systems can also be readily incorporated into the apparatus of the present invention. It is also within the scope of the present invention to mount each set of connectors (118, 120, 122, 124, 126, 128, 130, 132, 134, 136, 138, 140, 116, 115, 112, and 113) on a separate panel segment so that the each set of connectors or components can be readily replaced as a group.

It will be appreciated that the present invention advantageously allows additional features and equipment to be readily added. For example, the structure of the present invention allows telephone, alarm, and television devices to be readily added or changed. Moreover, access to any communication media leading to any enclosure in the structure can be made instantly. Even further, any necessary connection to be made to the information conveying media can be made at a central location.

Reference will next be made to Figure 4 which is a plan front view of the apparatus 100 represented in Figures 2A&B with exemplary interconnections made which convey information signals from one point to another in the structure. It will be noted that some of the wire restraining devices represented in Figure 4 are indicated at 174. Moreover, in Figure 4 not all connectors have been used and some connectors have not been installed in the panel.

In the example represented in Figure 4, interconnections have been made as indicated in Table B, Table C, and Table D. All of the interconnections are made using components which will maintain the integrity of the information signal carried thereon. For example, the interconnections involving twisted pair cables should adhere to the CAT5 standard while the coaxial cable and optical fiber interconnections should meet appropriate respective standards.

Set forth below in Table B are the interconnections represented in Figure 4 involving twisted pair cables. It will be appreciated that the information set forth in Table B is merely exemplary and many other arrangements of the present invention can be devised by those skilled in the art using the information set forth herein. TABLE B

Connector Interconnect Connector

116A 206A 118A

116B 206B 120A

116C 206C 122A

116D 206D 124A

116E 206E 126A

116F 206F 128A

116G 206G 130A

116H 206H 132A

1161 2061 132E

In the case of the preferred embodiment represented in Figure 4, the interconnections indicated in Table B provide telephone signals to the enclosures (e.g.. rooms) indicated in Figures 2A&B as 148, 150, 152, 154, 156, 158, 160, and 162. In the case of enclosure 162, two interconnections are provided which can convey telephone signals or any other information signal which can be conveyed using the twisted pair cables. Set forth below in Table C are the interconnections represented in Figure 4 involving coaxial cable. It will be appreciated that the information set forth in Table C is merely exemplary and many other arrangements of the present invention can be devised by those skilled in the art using the information set forth herein.

TABLE C

Connector Interconnect Connector

114A 204A 118D

114B 204B 132D

115A 202A 132C

115B 202B 130C

115C 202C 126C

115D 202D 128C

115E 202E 130C

In the case of the preferred embodiment represented in Figure 4, the interconnections indicated in Table C provide television signals from the apparatus 100 to the enclosures ( e . g. , rooms) indicated in Figures 2A&B as 148, 156, 158, 160, and 162. In the case of enclosures 148 and 162, television signals are conveyed to the apparatus 100 via connectors 114A and 114B where they are processed by the signal processor 172 and conveyed back to connectors 115A-E where other enclosures can receive such television signals as well as other television signals which may arrive from external sources.

Set forth below in Table D are the interconnections represented in Figure 4 involving optical fiber. It will be appreciated that the information set forth in Table D is merely exemplary and many other arrangements of the present invention can be devised by those skilled in the art using the information set forth herein.

TABLE D

Connector Interconnect Connector

112A 208A 128B

112B 208B 118B

113A 208C 118E

113B 208D 128E

In the case of the preferred embodiment represented in Figure 4, the interconnections indicated in Table D provide two independent fiber optic connections between the apparatus 100 and the enclosures ( e . g. , rooms) indicated in Figures 2A&B as 148 and 158. It will be appreciated that while the first preferred embodiment of the present invention has been explained using typical applications such as conveying telephone signals and television signals, any of the media can be used to convey whatever information signals which are compatible with the media. For example, digital data can be conveyed via twisted pair cable, coaxial cable, or optical fiber cable. Furthermore, the embodiments of the present invention can be readily expanded to include many different media provided within the structure and to receive information from many different media routed outside of the structure. The inclusion of optical fiber in the system of the present invention provides the advantage of allowing any type of information signal which may become common in the future to be accommodated due to the great bandwidth and immunity from interference which is provided by optical fiber. Moreover, optical fiber media provides the advantage of greater security from eavesdropping than other media.

Reference will now be made to Figure 4A which is a back plan view of a portion of the first embodiment represented in Figure 4. Figure 4A shows the cables which lead from the apparatus 100 to the enclosures or rooms (148, 150, 152, 154, 156, 158, 160, 162, 164, 166, 168, 170) represented in Figure 2. Figure 4A shows the logical and neat organization of the cables which are easy to identify and are held in place by wire restraining devices 174. This is in contrast to the prior art practice which leaves long lengths of disorganized cable (which are difficult to identify and trace) on the floor in a utility room.

Figure 4A shows the reverse side of the sets of connectors (the front side of which are generally represented as sets of connectors 118A-F, 120A-F, 122A- F, 124A-F, 126A-F, 128A-F, 130A-F, 132A-F, 134A-F, 136A- F, 138A-F, and 140A-F in Figures 2A&B) . All of the cables and connectors shown in the reverse side view of Figure 4A should also meet the appropriate standards discussed herein. Also represented in Figure 4A is a terminal strip 175 which is included to make convenient connections (not represented) between some devices, such as telephone system control box (173 in Figure 3) or intruder detection system which require the use of a terminal strip. The terminal strip 175 is preferably of a type which is well-known in the industry.

Also represented in Figure 4A is an adaptor 176 which has been fabricated in accordance with the present invention. The adaptor 176 provides a structure to convey telephone signals presented on a connector referred to in the art as an "Amphenol" connector (not represented in Figure 4A) to the CAT5 connectors included in the apparatus 100. It will be appreciated that the adaptor 176 is structured to convey one or more telephone signals to each of the twisted pair connectors 116A-L. As is known in the art, some telephone systems require only two conductors to convey a telephone signal while some telephone systems require four or more conductors. Since each twisted pair connector 116A-L (and twisted pair cables strung to the rooms) includes eight conductors, the adaptor 176 can be optionally structured to convey one, two, three, or four telephone signals on each twisted pair cable. Thus, the adaptor can be advantageously structured to convey several telephone or other information signals along a signal twisted pair cable.

Reference will now be made to Figure 4B which is an interior plan view of the back side of the embodiment illustrated in Figure 3. Represented in Figure 4B is a plurality of NEMA compatible receptacles which are arranged in a structure commonly referred to in the industry as a power strip 177. The power strip is connected to the AC power bus (not represented in Figure 4B) of the structure in which the apparatus 100 is installed. The power strip 177 is used to convey AC power to various devices associated with the apparatus 100. The power strip 177 is also used as a location to place modulated information carrying signals onto the AC power bus. As is known in the art, devices are available, and standards have been promulgated, which transmit modulated information signals on the AC power bus. It is within the scope of the present invention to incorporate such devices.

Also represented in Figure 4B is a mud ring 179. The mud ring 179 functions to allow passage of the plurality of cables making up the buses (which lead to the various rooms) to pass through the wall board (not represented in Figure 4B) next to which the apparatus 100 is placed. The mud ring 179 protects the edge of the wall board and the mud ring 179 allows the cables to be readily passed through the wall and connected to the apparatus 100.

Reference will next be made to Figure 4C. Figure 4C is a perspective view of another preferred embodiment, generally represented at 220, of the electronic information distribution apparatus of the present invention. The apparatus 220 represented in Figure 4C is particularly adapted for installations requiring less information distribution capacity than the previously described embodiment 100. The apparatus 220 is preferably installed in a wall cavity between two studs 16 as are commonly present in conventional construction.

The apparatus 220 includes a terminal strip generally represented at 226, eight sets of connectors generally represented at 228, a set of twisted pair cable connectors generally represented at 330 which preferably function to distribute telephone signals, a set of coaxial cable connectors generally represented at 334 which preferably function to distribute other signals (such as those provided by cable television and other utility companies and internal signal sources) , and a set of connectors generally represented at 334 which function to receive information signals provided by any available sources. All of the connectors (226, 228, 330, 332, and 334) are supported on a panel 224. A cover 222 is provided which hingably opens and closes over the panel 224. The cover 222 allows the apparatus 220 to be installed in a location such as a hall or closet (not represented in Figure 4C) . The cover 222 is generally dome shaped to accommodate the interconnecting cables (not represented) when the cover 222 is closed. Reference will next be made to Figure 5 which is a perspective view of a portion of a second presently preferred embodiment of the present invention. As explained above, each room or enclosure in a structure is preferably provided with two twisted pair cables, two coaxial cables, and two optical fibers. Not only is there no recognition in the prior art to include the above-described bus arrangement to each room, but there is no suggestion in the art to provide a convenient and efficient structure to allow connections to be made to all of such cables in each of the rooms of the residential dwelling. Moreover, in contrast to the prior art, the present invention allows information to be conveniently disseminated from one room to another room (or rooms) in the structure or even to a recipient outside of the structure such as a utility company providing a connection to the apparatus. Figures 5 and 6 will be used to explain how the second presently preferred embodiment of the present invention carries out the function of providing a compact device to connect devices which may be present in the room to one or more of the buses.

Represented in Figure 5 is a plate which provides high density packaging of connectors which are connected to the two twisted pair cables, two coaxial cables, and two optical fiber cables strung to each room as represented in Figures 2A&B. Once again the present invention has particular application in a residential dwelling but may also be used in many other applications. It will be appreciated that residential dwellings will in the future require support for devices such as computer networks, phone systems, fax machines, modems, CCTV, appliance automation systems, lighting control systems, power line controllers, audio/video signals, control systems and numerous other electronic devices.

Represented in Figure 5 is a plate 266 which includes an aperture 270, the aperture 270 accommodating a NEMA standard wiring device, and six adaptable apertures 272A-F. As used herein the term "wiring device" means any device which receives energy via a cable or wire and include both passive and active devices which are now available in the industry and those which may become available in the future. The plate 266 rests flush on the surface of a wall where access to the bus is needed. Each of the adaptable apertures 272A-F can accommodate one twisted pair cable connector, one coaxial cable connector, or one optical fiber connector (not illustrated in Figure 5) such as those described earlier in connection with Figures 2-4. Thus, the plate 266 can accommodate any combination of up to six twisted pair connectors, coaxial cable connectors, and/or optical fiber connectors. The holes 268 are provided to allow screws or bolts (not illustrated) to attach the plate 266 to an electrical box as will be explained next.

Figure 6 provides a perspective view of the portion of the second embodiment which is installed within the wall of the room. Indicated at 252 is an electrical box which is dimensioned in accordance with customary industry standards and as available in a plastic or metal material in the industry. A fin 262 is often provided on the box 252 to receive a nail or a screw by which the box is attached to a building structure element (not represented) as known in the art. Two bores 264 are provided to receive screws or bolts to hold the plate 266 (Figure 5) in place. Figure 6A provides an exploded perspective view of the structures represented in Figures 5 and 6 with cable connectors, generally designated at 276, ready to be inserted into the plate 266.

In contrast to the present invention, the prior art approach is to feed twisted pair cables, coaxial cables, and optical fibers through a standard electrical box such as that represented at 252 in Figure 6. Disadvantageously, use of a customary electrical box 252 poses several problems. For example, coaxial cable and twisted pair cable do not easily fit into an enclosed electrical box. Damaging kinks can occur in the cables during the installation process or when wall board is installed around the electrical box 252 since it can be very difficult to roll the cables back into the electrical box 252 during the "rough-in" phase of dwelling construction. Moreover, when the hole is being cut in wall board to fit the electrical box 252, such as when a power tool is used as known in the industry, the cables may be damaged.

All of these drawbacks are aggravated when optical fibers are used. Because of the limited bend radius of optical fibers, the prior art closed electrical box 252 makes it difficult or impossible to roll the loose optical fiber cable into the electrical box 252 while wall board is being installed. While optical fiber cable is surprisingly strong and tough, bend radius limitations should not be exceeded by stuffing the optical fiber cable into the electrical box 252 during installation of the wall board or damage will result. Even after the installation of wall board on a wall, the closed construction of the standard electrical box 252 makes installing cable difficult because the cables push against the back side of the box and, particularly in the case of optical fiber cable, may result in damage to the fiber or cable.

Furthermore, some attempts have been made to attach a separate closed electrical box, which can receive information carrying cables, to the standard electrical box 252. Such approaches have experienced problems such as: the separate box breaking off when the wall board is installed; the separate box irretrievably falling within the wall cavity; the cover plate being difficult or impossible to correctly install; and the separate box does not lay flush with the surface of the wall. The apparatus described herein overcomes all of these problems.

It will be appreciated that the connectors used in the apparatus represented in Figures 2A&B-4 can also be used in the plate 266 (Figure 5) . Thus, the desired connectors can be inserted into the adaptable apertures 272A-F in accordance with the particular needs at each site. It is within the scope of the present invention to include additional wiring device apertures 270 of the same or different configuration or to include additional adaptable apertures 272A-E. Thus, the connectors can be installed in the plate 266 to accommodate two voice phone lines, a modem phone line, and a fax line using adaptable apertures 272A-D with the remaining two adaptable apertures 272E-F being filled with appropriate "blanks." Thus, when necessary, additional connectors can be attached to, for example, the optical fibers present at the plate 266 but not yet used. Referring still to Figure 6, in order to facilitate use of the previously mentioned cables, and particularly optical fibers, the second embodiment of the present invention includes a mounting frame generally indicated at 250 which overcomes the problems associated with the prior art separate boxes. The mounting frame 250 has an open back as indicated generally at 258. The mounting frame 250 is preferably attached to the electrical box 252 by a double sided adhesive tape 274. Other structures, such flexible fingers that extend from the electrical box 252 or from the perimeter 254 of the mounting frame 250, can also be used to attach the mounting frame to the electrical box 252. Bores 260 are provided to receive screws or bolts to hold plate 266 (Figure 5) in place. It will be appreciated that is also within the scope of the present invention to adhere or attach the mounting frame 250 directly to structural building members.

Importantly, the open back construction of the mounting frame 250 allows more room for cables, particularly optical fiber cables, to bend. During installation of wall board, the cables are left inside the cavity of the wall and can be pulled through the opening 258 of the mounting frame 250 when connectors

(not shown) are installed. Moreover, with the open back construction, ample space is provided to accommodate the bend radius of cables and particularly optical fibers. If desired, extra cable can be left inside of the cavity of a wall to accommodate future expansion. A cable restraining device (not shown) can optionally be included on the mounting frame 250 for holding the cables in place and relieving strain on the connectors which are installed in the adaptable apertures 272A-F.

Still referring to Figure 6, a flange 256 is provided around three sides of the mounting frame 250 which prevent the mounting frame from being pulled through the wall board. Thus, when screws are tightened through holes 268 (Figure 5) into bores 264, the mounting frame 250 is held behind the wall board (not shown) and the plate 266 can be tightened against the wall (not shown) securing both the mounting frame 250 and the plate 266 in place. It will be appreciated that the mounting frame 250 can be used both in new construction and to retrofit existing structures. In the case of retrofitting an existing structure, after a rectangular hole is cut in the wall board next to an existing electrical box, the mounting frame 250 can be slipped into the hole on its side, rotated 90 degrees, and adhered to the existing electrical box. The cables can then be fished into place, as known in the art, and the cables attached to appropriate connectors and the plate 266 installed. The flange 256 holds the mounting frame 250 behind the wall board and the perimeter 254 of the mounting frame 250 extends close to the edge of the sheetrock. In accordance with the National Electrical Code (NEC) , the perimeter should be set back no farther than 1/4" from the surface of the wall so different sizes of mounting frames 250 are preferably provided for differing thicknesses of wall board.

While the plate 266 is one preferred arrangement for holding cable connectors in a convenient wall- mounted position, several drawbacks can be encountered in some situations. For example, the width of the electrical box 252 (Figure 6) is not standard within the electrical industry and can vary significantly. Thus, as the width of the electrical box 252 varies, after the mounting frame 256 (Figure 6) is attached the bores 260 and 264 (Figure 6) do not properly align with the holes 268 provided in the plate 266 (Figure 5) sometimes causing serious difficulty during installation. Moreover, when more than one or two cable connectors 276 are attached to the plate 266, the installation of the plate 266 can still be time consuming and difficult due to the stiffness of the cables and the care needed to avoid damaging the cables. Still further, the cables and connectors must be protected from damage due to cutting and painting while the wall is finished. Even further, if the mounting frame 254 is mounted on the side of the electrical box 252 opposite from that shown in Figure 6A, the plate 266 must be installed upside down and the connectors, such as a RJ-xx series jack and SC fiber optic connectors, appear to a user to be upside down also since the twisted pair RJ-xx series jack can only be installed in plate 266 in a single orientation. The installation of connectors upside down is not desirable.

Reference will next be made to Figures 6B-G to describe additional preferred structures used to hold cable connectors in a wall mounted position. Figure 6B provides a front view of an existing electrical box 252 attached to a stud 16 by way of nails or screws 212. Also represented in Figure 6B is a bundle of cables 280 which have been installed in the residential or commercial structure. The bundle of cables 280 is releasably held in place against the stud 16 by a grasp 278. The grasp 278 can preferably be a strip of hook and loop fastener which is nailed to the stud 16 or any other similarly functioning arrangement can be used within the scope of the present invention. It will be appreciated that the method and structure described in connection with Figures 6B-G works equally well if only a single cable is installed in contrast to a number of cables being included in the bundle of cables 280.

The bundle of cables 280 are positioned far enough away from the electrical box 252 so that there is no possibility that the cables will be damaged when a hole is cut from the wall board (not represented in Figure 6B) to access the electrical box 252. With the present invention, the bundle of cables 280 are kept relaxed and are not subject to kinking which results when they are forced into a box. Moreover, the bundle of cables 280 are positioned so that after installation of the wall board the bundle of cables 280 is shielded from paint which is applied to the wall board. It is also within the scope of the present invention to provide a removable covering over the end of the bundle of cables 280 to provide further protection, however, such is often not required when using the structures herein described. Connectors may be attached to the ends of the cables either before or after the installation of wall board to the stud 16. Thus, the described arrangement protects the bundle of cables 280 from damage which might otherwise arise from the cutting of holes in the wall board and painting of the wall board. Before the installation of wall board and the cutting of holes in the wall board to provide access to electrical boxes and other utilities, a template 276 is attached to the electrical box 252 preferably using screws inserted into bores 264. When attaching wall board to the stud using screws or nails, the electrical box 252 is generally used as a guide for a cutting tool by the wall board installer so that the hole which is cut in the wall board closely matches the shape and size of the electrical box 252 for a close fit thereto. The template 276 similarly acts as a guide for a cutting tool so that a properly sized hole can readily be made in the wall board to accommodate a holder for the connectors included on the bundle of cables 280 as will be described shortly. Advantageously, the template 276 allows the hole to be cut in the wall board in the same manner and at the same time as the hole in the wall board is cut for the electrical box 252. The template 276 is preferably removed after the hole is cut in the wall board. Alternatively, it is within the scope of the present invention to fabricate the template 276 so it can remain in place after installation of the cable connection holder as will now be described. Figure 6C provides a front view of a cover plate

282 in accordance with one aspect of the present invention. The cover plate 282 can be fabricated from metal, plastic, or any other suitable material. Provided in the cover plate 282 are apertures 287 which are exemplary of the apertures which accommodate NEMA wiring devices. It is to be understood that the apertures 287 are merely exemplary of the different wiring devices which can be accommodated.

In the embodiment illustrated in Figures 6B-F, six apertures 288A-F are also provided to allow access to the cable connectors, for example, the connectors 276 in Figure 6A. Importantly, the cover plate 282 does not provide any structures to which the connectors 276 attach (as does cover 266 in Figure 6A) but the connectors merely project into the apertures 288A-F. A plurality of screw holes 285 are provided to attach the cover plate 282 to the electrical box 252 and to other connector holding structures to be explained shortly. The screw holes 285 can have an oval shape to accommodate precise positioning of the cover plate 282. Importantly, using the structures described in connection with Figures 6B-G, the structures to which the cover plate 282 are attached can be beneficially precisely positioned so that the screw holes 285 can be of a circular, rather than oval, shape. Figures 6D-E provide front and side views, respectively, of a capture plate 284 which functions to securely hold the connectors 276 in place. The connectors 276 can preferably be those which are available in the art and each of six, or some other number, of apertures 288A-F which are each shaped to securely hold the connectors which are inserted therein. The side view of Figure 6E shows the offset of the apertures 288A-F which provide that the connectors, when secured therein, to properly project into each of the apertures 183A-F (Figure 6C) .

Figure 6F provides an illustration of the electrical box 252 with an electrical receptacle mounted therein and a mounting frame 292 placed in a hole 290 which has been formed in the wall board as described in connection with Figure 6B. Also illustrated in Figure 6F are formable fingers 294 which are attached to the mounting frame 292 and bend to hold the mounting frame 292 within the hole 290. The mounting frame 292 is provided with screw bores 296 which receive screws 289 placed through the respective bores 286 in capture plate 284. The bores 286 are preferably oversize, and can be an oval shape, to allow the capture plate 284 to be precisely positioned when fastened into place. With the cable connectors 281 inserted into the appropriate apertures 288A-F of the capture plate 284, the installation of the cable connector holding structures in the wall is greatly simplified and improved over the previously available schemes. The cover plate 282 is secured into place using screws 291 which are received through respective screw holes 285 in cover plate 282 and are threadably received by bores 293 provided on the capture plate 284. It is also within the scope of the present invention to secure the cover plate 282 in place using magnetized materials (particularly when the cover plate 282 is fabricated from a metallic material) or using a releasable catch structure as known in the art (particularly when using a cover plate 282 fabricated from a plastic material) .

The structures represented in Figure 6F allow the positioning of the capture plate 284 to be precisely controlled making the installation easier and often cosmetically more appealing than possible with previously available schemes. It will also be appreciated that the template 276 (Figure 6B) can be formed to allow multiple capture plates 284 and mounting frames 292 to be installed side-by-side. Using the information set forth herein, additional cover plates can be fabricated to allow multiple capture plates 284 and mounting frames 292 to be installed side-by-side.

Figure 6G illustrates the structures shown in Figure 6F but in a reversed view. Since the cable connectors 276 (Figure 6A) are attached to the capture plate 284, rather than to the cover plate 282, the cable connectors can be properly oriented in those instances where the connector (such as with RJ-xx series twisted pair connectors and SC style fiber optic connectors) which have a proper vertical orientation. With the arrangement represented in Figure 6G, the capture plate 284 is installed as described in connection with Figure 6F and the cover plate 282 is readily positioned in a reversed orientation. Thus, the orientation of the connectors 276 is properly maintained while the cosmetic appearance of the cover plate 282 is also preserved. Also provided in Figures 6H-I are alternative cover plate 282A-B, respectively, arrangements. Figures 6H-I show that the arrangement of the apertures can vary to accommodate differing needs and the necessary capture plates to accompany use of cover plates 282A-B can be readily arrived at using the information set forth herein.

The structures described in connection with Figures 6B-G allow the installation of cable holding structures in a wall, either in new construction or in a retrofit application, to proceed more efficiently than previously possible. The mounting frame 292 has an open back so that the cables are not crimped or unduly bent . Further, the bundle of cables 280 are held out of the way of damage during the installation of wall board and application of paint thereto but can be easily retrieved for installation into a cable connector holding structure. The structures also provide a more aesthetically desirable appearance since the positioning of the structures can be precisely adjusted. Reference will next be made to Figures 7-8 to explain another aspect of the present invention. As indicated above, the signal processor 172 (Figures 2A&B) provides the functions of combining, modulating, and conditioning any signals which enter a structure or which originate within the structure. In order to provide the advantage of taking whatever information which is presented by a utility provider and disseminating the information to one or more rooms of a structure, the electronic information signal interface represented in Figures 7 and 8 is furnished. Figures 7 and 8 are high level functional block diagrams of the interfaces and those skilled in the art can readily arrive at numerous different embodiments thereof using the information set forth herein. While the electronic information interfaces represented in Figures 7 and 8 have particular use in the earlier described embodiments of the present invention, the apparatus and methods described in connection with Figures 7 and 8 can be advantageously used in other applications.

Represented in Figure 7 is an electronic information signal interface which preferably includes a microprocessor 300. The microprocessor 300 can be any of a number of microprocessors which are now available or which may become available in the future. Alternatively, the functions of the microprocessor 300 may be carried out by other suitable devices. For example, the microprocessor 300 can preferably be one available from Motorola and referred to as the Power PC series of RISC (Reduced Instruction Set Computer) microprocessors. Those skilled in the art can readily arrive at any additional components which can beneficially be associated with the microprocessor 300, such as memory or peripheral devices, as well as the necessary programming code.

Also represented in Figure 7 is a power supply 302. The power supply 302 provides the necessary electrical power to components represented in Figure 7 and can be readily devised by those skilled in the art.

As indicated earlier, the apparatus of Figure 7 operates to interface with electronic information signals (both those signals which are received from utility providers originating outside the structure and signals which are generated within the structure) having one or more inherent signal protocols and to allow the dissemination of an information signal having a common protocol throughout the structure and which embodies the information conveyed by the original information signals. Represented in Figure 7 are bidirectional communication modules 304. The bidirectional communication modules 304 are intended to provide two way communication with an information using device located ether outside of the structure, for example a residential structure, or inside of the structure. A first bidirectional communication module 304A preferably includes devices necessary to connect to a coaxial cable, such as the coaxial cable commonly used to convey television signals by a cable television provider. The first bidirectional communication module 304A includes the components necessary to demodulate, and in order to allow transmission as well as reception of information signals the components necessary to modulate, radio frequency carriers and preferably also includes appropriate analog-to-digital and digital-to-analog convertors.

The first bidirectional communication module 304A is connected to a coaxial port represented at 305A which leads to a network of a utility provider or some other information generating device. While the apparatus of the invention represented in Figure 7 preferably processes information in a digital form, it will be appreciated that the apparatus of the present information could also be implemented to process information in an analog form.

Also represented in Figure 7 is a second bidirectional communication module 304B. The second bidirectional communication module 304B preferably includes devices necessary to connect to a twisted pair cable, such as the twisted pair cable commonly used to convey telephone signals by a telephone utility provider. The second bidirectional communication module 304B also includes the components necessary to transmit and receive information signals on a twisted pair port represented at 305B. Also preferably included are appropriate analog-to-digital and digital-to-analog convertors. The second bidirectional communication module 304B is connected to the twisted pair port 305B which leads to a network of a utility provider or some other information generating device.

Each of the bidirectional communication modules 304 are linked to a DSP 308B via a data path represented at 305C. The DSP 308B, and DSP 308A, are both digital signal processors such as those available from Texas Instruments, Analog Devices, Motorola, AT&T, and others. As known in the art, a digital signal processor is a programmable processor that, unlike a generally purpose processor such as the microprocessor 300, is programmed to perform one kind of processing at a time. Thus, while a general purpose processor is required to process all kinds of data in a variety of ways, a digital signal processor is intended to repeat the same process over and over on a particular kind of data, for example, digital video data, until reprogrammed to process another kind of data. It will be appreciated that only one DSP, or several DSPs, may be included in the apparatus in accordance with the principles of the present invention.

It will be appreciated that the microprocessor 300 works closely with, and controls the operation of, the DSPs 308A and 308B. The microprocessor 300 communicates with the DSPs 308A and 308B via lines 300A over which data and instructions pass. Those skilled in the art will realize the great advantages which accrue through the use of digital signal processors and will be able to arrive at appropriate programming code needed to perform specific interfacing and converting tasks.

It will be understood that the information conveyed to the bidirectional communication modules 304A&B via ports 305A&B may be analog or digital information complying with any number of different protocols inherent in the information being transmitted. The DSPs 308A&B, the microprocessor 300, and the bidirectional communication modules 304 together function to convert the information presented to the bidirectional communication modules 304 from any inherent protocol present in the signal to an information signal utilizing a common protocol which is dispatched on an output port represented at 312 to be disseminated to any number of devices as hereinbefore described.

The modularity of the bidirectional communication modules 304, as well as the modularity of the other devices described in connection with Figures 7 and 8, allow features and capacity to be added or removed from the apparatus as desired. Moreover, it is preferred that the data paths represented in Figures 7 and 8, for example data path 305C, be implemented as a fiber optic back plane into which the bidirectional communication modules 304, as well as other modules and devices represented in Figures 7 and 8, connect to communicate with the DSPs 308A&B and to other devices. It is preferred that the data path 305, as well as all of the data paths between devices and the DSPs 308A&B, employ fiber optic devices. Thus, with the use of fiber optic devices and techniques, the data paths will provide sufficient bandwidth for speedy conveying of large volumes of digital data. The data paths may also be formed using available electrical connections, as are known in the art, within the scope of the present invention.

Also represented in Figure 7 are utility communication modules 306. The utility communication modules 306 are particularly adapted to provide communication with an information carrying medium provided by a utility provider. A first utility communication module 306A preferably includes devices necessary to connect to a fiber optic cable, such as the fiber optic cable used by some utilities to convey telephone and data signals by a telephone service provider. The first utility communication module 306A includes the components necessary to demodulate and, in order to allow transmission as well as reception of information signals, devices which can modulate light carriers onto a fiber optic cable. The first utility communication module 306A also preferably includes appropriate components to provide digital data to the DSP 308A. The first utility communication module 306A is connected to a fiber optic port represented at 307A which leads to the network of a telephone service provider or some other information generating device. Also represented in Figure 7 is a second utility communication module 306B. The second utility communication module 306B preferably includes devices necessary to connect to a coaxial cable, such as the coaxial cable commonly used to convey television signals. The second utility communication module 306B also includes the components necessary to transmit and receive information signals on a coaxial cable port represented at 307B. The second utility communication module 306B is connected to the coaxial cable port 307B which leads to a network of a utility provider or some other information generating device.

Each of utility communication modules 306 are linked to a digital signal processor 308A via a data path represented at 307C. It will be understood that the information conveyed to the utility communication modules 306A&B via ports 307A&B may be analog or digital information complying with any number of different protocols. The DSPs 308A&B, the microprocessor 300, and the utility communication modules 306 together function to convert the information presented to the utility communication modules 306 from any inherent protocol present in the signal to an information signal utilizing a common protocol which is dispatched on an output port represented at 312 to be disseminated to any number of devices as hereinbefore described.

It will be appreciated that the reference "utility communication module" refers to an intended function of the module and is not intended to limit the applications to which the module or modules can be employed. Communication modules can also be configured to receive and transmit radio frequency carriers to be broadcast into the air to establish a communications link. Communication modules can also be configured to receive and/or transmit information via the AC power line as discussed earlier. The power supply 302 can be readily used as a location for inserting information signals on, and extracting information signals from, the AC power line. The apparatus represented in Figure 7 is flexible and can accommodate devices which function to further process, decode, and/or manipulate data.

Also represented in Figure 7 are feature modules 310. The feature modules 310 are particularly adapted to process data which is handled by the apparatus. A first feature module 310A preferably includes devices necessary to decode a satellite television receiver signal which may be received by another module. Such data is passed to the first feature module 310A from the DSP 308A, and back again, via a data path 310C.

Also represented in Figure 7 is a second feature module 310B. The second feature module 310B preferably includes components necessary to function as a video line doubler performing the task of enhancing the image generated by an video signal as known in the art. The second feature module 310B also preferably includes appropriate components to provide digital data to the DSP 308B which are conveyed by the data path 310C. Feature modules can also be configured for interfacing with home automation devices, such as those described herein, which conform to any of the now promulgated standards or any standard which may be promulgated in the future. The apparatus also can be configured to perform the routing of information packets necessary for the CEBus and Echelon home automation standards. Reference will next be made to Figure 8 which is a high level functional block diagram of another electronic information interface in accordance with the present invention. The apparatus illustrated in Figure 8 follows generally the structure shown in Figure 7 and is of a configuration which is particularly adapted for use in a residential structure which includes only connections to a telephone service provider and a cable television service provider. It will be appreciated that, as explained in connection with Figure 7, the apparatus of Figure 8 can be expanded as the need arises.

The apparatus of Figure 8 includes a microprocessor 400 which preferably is selected in accordance with the characteristics described in connection with the microprocessor 300 represented in Figure 7. Similarly, power supply 402 and DSP 408A are preferably selected in accordance with the same criteria as the corresponding components represented in Figure 7.

Included in the apparatus of Figure 8 are communication modules 406A and 406B. The communication module 406A is particularly configured to connect to a fiber optic network at port 407A. The fiber optic network can carry a variety of information signals most preferably as digital data as now available or as will become available in the future. The communication module 406B is particularly configured to connect to a coaxial cable network at port 407B. The coaxial cable network preferably carries television signals and other signals such as commonly provided by cable television service providers.

The communication modules 406A and 406B each include an interface 409A or 410A which receives the incoming information signal and includes components and software needed to accept the signal. Importantly, each of the interfaces 409A and 410A is configured to appear as the correct device to the utility provider service. For example, if in the case of communication module 406A which is connected to the telephone network, the interface 409A is configured to appear as a device which is generally provided by the telephone service provider. In the case of communication module 406B which is connected to the cable television network, the interface 410A is configured to appear as a device which is generally provided by the cable television service provider. Each of the interfaces 409A and 410A must be configured to properly emulate the utility service provider equipment. Such equipment may conform to a widely promulgated protocol or may conform to a privately held proprietary protocol .

Each of the communication modules 406A and 406B also carry out the function of a protocol converter 409A and 41OB. The protocol convertors 409A and 41OB, in cooperation with DSP 408A, convert the information inputted to the communication modules 406A or 406B, which may adhere to any number of inherent protocols, and result in an output signal which adheres to a common protocol which is recognizable by all of the devices which will receive such information. For example, all of the devices which are located in the structure described above in connection with Figures 2A&B can be readily configured to accept and recognize the common protocol. Examples of such devices include televisions, computers, smart appliances, and other devices such as those described earlier.

In the case of bidirectional communication, the protocol converters 409B and 410B and the interfaces 409A and 410A manipulate and convert the information for transmission from the port 407A and the port 407B, respectively. The input/output of the apparatus is represented in Figure 8 at port 412.

The apparatus of the present invention provides flexibility which has not hitherto been available in the art . The apparatus represented in Figures 7 and 8 can preferably be programmed to fulfill a variety of different applications. Indeed, since the preferred apparatus of Figures 7 and 8 is substantially entirely software driven the apparatus most advantageously can be adapted for different applications via programming downloaded at the apparatus, generally at the node zero location, or the programming can be downloaded from a remote location. For example, the microprocessor 300 or 400 is programmed to monitor the incoming information present on the utility provider's line and recognize commands which allow downloading of programming from a central office location. The downloading of new programming can carry out numerous changes in the functioning of the apparatus. For example, the programming downloaded from a central office can allow the customer to access, or deny access to, particular features of utility service, such as a pay-per-view television service.

The programmability of the apparatus of Figures 7 and 8 allows features which have not otherwise been available in the industry. For example, the apparatus can be connected to numerous utility service providers and allow the customer to choose from among all of the providers and convey billing information to the provider. As a further example, the apparatus can allow the customer to have long distance telephone calls routed to any one of a number of different utility service providers, the choice of which utility service provider being based on such factors as the service provider's rates, the destination of the call, or even the telephone number being called. Thus, the apparatus represented in Figures 7 and 8 acts as a gateway allowing only authorized information to enter and leave the distribution system. Moreover, the apparatus is also programmed to allow information such as automatic utility meter reading data, encrypted electronic banking information, high speed data communication, and other information to enter and leave the apparatus.

Reference will next be made to Figure 9 which is a diagrammatic representation of a telephone line distribution hub 350 which is available in the industry. The line distribution hub 350 is commonly attached to a telephone system control box, such as telephone system control box 173 in Figure 3, which are commonly available in the art and which can be readily integrated into the systems described herein. Such telephone system control boxes are often part of a KSU or PBX internal telephone switching system such as those available in the art and those described earlier. In accordance with the benefits obtained with earlier described aspects of the present invention, it is very desirable to include components in embodiments of the present invention necessary to accommodate the future expansion of the system. In customary installations, a telephone system control box is directly connected to the a 50 position connector 354 as is known in the industry. When the 50 position connector 354 is attached to a corresponding connector (not represented) leading to a telephone system control box, different internal telephone lines are presented at each of the jacks (some of which are labeled at 352 and which preferably comply with the RJ-xx series standards which are well-known in the industry) . The signals which are presented at the jacks 352 can then be patched to different locations in the building as described earlier in connection with Figure 4. Significantly, if an internal telephone system is not installed, the telephone line distribution hub 350 is not of any practical use in the prior art schemes and thus is not installed. In accordance with the present invention, the telephone line distribution hub 350 (or an equivalent structure) is installed in all instances, even where an internal telephone system is not contemporaneously installed but may be obtained in the future. In order to utilize the telephone line distribution hub 350 even though an internal telephone system is not installed, a line adapter plug 356 in accordance with one aspect of the present invention is provided. The line adapter plug 356 is wired so that all of the jacks 352 are connected in parallel when the line adapter is used. The connection of the jacks 352 in parallel is schematically represented in Figure 9A. One skilled in the art can readily wire the line adapter plug 356 to connect all of the jacks 352 in parallel in accordance with the information set forth herein. Thus, a telephone line distribution hub 350 can be installed ready for future connection to an internal telephone system control box but can also function to connect a telephone line signal placed onto one of the jacks 352 to all of the jacks 352. In this way, the telephone signals present on the jacks 352 can be patched through to all of the twisted pair locations throughout the building but will be joined to a single telephone line until a internal telephone system (for example a KSU or PBX) is obtained.

It will also be appreciated that it is within the scope of the present invention to provide the line adapter plug 356 to connect, for example, half of the jacks 352 in parallel with the remaining half of the jacks also wired in parallel. Thus, two telephone lines can be patched using the telephone distribution hub 350. Importantly, when an internal telephone system is obtained, the telephone system control box is directly connected to the 50 position connector 354 and a multiple line telephone system is ready for use with negligible or no rewiring. Reference will next be made to Figure 10 which is a representation of an audio signal distribution system 376 in accordance with another aspect of the present invention. It will be appreciated that the audio signal distribution system 376 can be used alone in a building or can be integrated into other systems described herein, for example those systems described in connection with Figures 2A&B, 3, and 4A-C. The components illustrated in Figure 10 can preferably be provided with customary rack mounting structures as described earlier.

Provided on the audio signal distribution system 376 are a plurality of audio device line level outputs, each pair of outputs being labeled 378A-D. Each pair of line level outputs 378A-D preferably include a first connector for the left channel and a second connector for the right channel, each of the connectors preferably being an industry standard RCA phono jack. The illustrated structures can also be used to convey monaural audio signals as well. Each of the line level outputs 378A-D is connected to the output of a specific audio device, such as a tuner 377A, compact disc player 377B, cassette tape deck 377C, or another device 377D which provides an output. The devices providing program source material can be located anywhere in the structure and their signal conveyed as described earlier. Also provided are a plurality of speaker inputs 380A-H, each assigned to one of eight different zones in a building (381A-H) , each of which leads to a speaker, or a speaker connection, in one of the zones. Each of the speaker inputs 380A-H are preferably connectors known in the industry as "banana jack" connectors also with provision for attaching bare wires thereto. Most preferably, a plurality of amplifiers 384A-C are associated with the audio signal distribution system. Each of the amplifiers is provided with a left channel and right channel line level inputs 388A-C as well as left channel and right channel speaker level outputs 390A-C. Each of the amplifiers 384A-C is provided with a gain control 386A-C. One exemplary patch cord having phono plugs on each end is represented at 383 and preferably can be used to connect the audio device line level outputs 378A-D to line level inputs 388A-C. Another exemplary patch cord having banana plugs on each end is represented at 385 which preferably can be used to connect the speaker level outputs 390A-C to any one of the one of the speaker inputs 380A-H. The banana plugs can conveniently be plugged into each other allowing more that one of the speaker level outputs 390A-C to be connected to more than one of the speaker inputs 380A-H.

It will be appreciated that the components represented in Figure 10 provide front mounted access to both signal connections and controls. Providing signal connections in a front panel location affords ease of access and convenience which is not otherwise possible with previously available schemes. In contrast to the present invention, conventional wisdom dictates that the signal connections on amplifiers and similar equipment be hidden on the rear of the equipment for utility and cosmetic reasons. Moreover, the arrangement represented in Figure 10 provides easy to understand labels for each of the building zones which allows a user, for example a homeowner, to readily make any desired changes. For example, the user need not move any furniture or equipment to gain access to the rear of the equipment . In contrast, the prior art schemes are often inconvenient, confusing and unreliable, particularly when changes are made by a homeowner. Reference will next be made to Figures 11A-C. Figure 11A provides a plan view of a room which has been equipped as a home theater. It is becoming more common that a room in residential buildings are devoted to viewing audio/video recordings. In those cases where the audio and video quality approaches that experienced in a motion picture theater, the term "home theater" is commonly applied to such audio/video systems.

As can be appreciated from an examination of Figure 11A, a number of cables must be strung to equip a typical home theater installation. Provided below in Table E is the identification of the components and cables shown in Figure 11A.

TABLE E

Reference No. Device Interconnection Wall mounted cable jack

444 Audio/Visual 444A equipment

446 Left Rear 446A 446B speaker

448 Left Front 448A 44BB speaker

450 Center speaker 450A 450B

452 Video screen ---

454 Right Front 454A 454B speaker

460 Sub woofer 460A 460B

456 Right Rear 456A 456B speaker

458 Video projector 458A

462 Connection to other sources/devices

The number of cables indicated in Figure 11A, all of which must be properly connected, can be confusing, especially to a new homeowner who just moved into a residential dwelling. Until the advent of the system of the present invention, in those instance where the cables were hidden in the walls, the cables often were left merely protruding from a hole in a wall near the location of the audio/visual equipment 444. Such schemes are both inefficient when connecting the cables to audio/visual equipment 444, particularly when a new owner moves into a residential dwelling, and often lead to an unsightly jumble of cables where the cables are gathered together.

In accordance with the present invention, a home theater signal distribution panel, generally indicated at 426, is provided. The home theater signal distribution panel 426 is preferably installed in a wall W, as indicated in the side view of Figure lie, near the location of the audio/visual equipment 444 (Figure 11A) .

As can be seen in the front view of Figure 11B, the home theater signal distribution panel 426 provides a central location where the cables are terminated so that the audio/visual equipment can be readily connected to the proper components. Advantageously, the home theater signal distribution panel 426 can be installed with the necessary cables at the time the building is constructed and thus the audio/visual equipment can be readily connected whenever desired. Provided below in Table F are the preferred cable interconnections between provided on the front surface 428 of the home theater signal distribution panel 426 and the various components illustrated in Figure 11A. It is preferred that the cable interconnections represented in Figure 11A lead from the home theater signal distribution panel 426 to wall mounted jacks, available in the industry, to allow ready connection and disconnection of different components.

TABLE F

Reference No. Device Interconnection Wall mounted cable jack

430D Left Rear 446A 446B speaker

430A Left Front 448A 448B speaker

430B Center speaker 450A 450B Reference No. Device Interconnection Wall mounted cable jack

43OA Right Front 454A 454B speaker

430E Sub woofer 460A 460B

430F Right Rear 456A 456B speaker

Each of the speaker connections (430D, 430A, 430B, 430A, 430E & 430F) are preferably connectors known in the industry as "banana jack" connectors with provision for attaching bare wires thereto also. Each of the speaker connections are also preferably labeled as indicated in Figure 11B.

Also preferably provided in the home theater signal distribution panel 426 are twisted pair connectors 432AS.B. The twisted pair connector 432A is preferably a connector complying with the CAT5 standard as explained earlier. The twisted pair connector 432B is preferably an industry standard RJ-45 connector. Also preferably provided in the home theater signal distribution panel 426 are fiber optic connectors 434A&B. Also preferably provided in the home theater signal distribution panel 426 are coaxial cable connectors 436A&B. The twisted pair connectors 432A&B, fiber optic connectors 434A&B, and coaxial cable connectors 436A&B are preferably connected to an electronic information distribution system such as that described in connection with Figures 2A&B, 3, and 4A-C. The bundle of cables 462 are attached to twisted pair connectors 432A&B, fiber optic connectors 434A&B, and coaxial cable connectors 436A&B and lead from the home theater signal distribution panel 426 to a central distribution system, such as that represented in Figures 2A&B, 3, and 4A-C. It will be appreciated that a variety of signals can be sent to, and dispatched from, twisted pair connectors 432A&B, fiber optic connectors 434A&B, and coaxial cable connectors 436A&B. A coaxial cable connector 438 is also preferably provided leading to a connector adjacent to the video projector 458.

It will be appreciated that rather than the speaker level signals being distributed, line level signals can be distributed within the scope of the present invention. Moreover, those skilled in the art will appreciate that the system represented in Figures 11A-C can be adapted for use with proprietary audio systems and techniques ( e . g. THX^® and AC-3™ techniques) which are now available or which may become available in the future.

In the side view of Figure 11B, a cover 440 is provided. The cover 440 is attached to the home theater signal distribution panel 426 by way of a hinge 440C so that the cover 440 can swing in the direction of arrow 440A. A lock 441 is preferably provided on the cover 440 so that the cover 440 can be locked in its closed position. A gap 440B is provided to allow a bundle of cables (444A in Figure 11A) access to the connectors shown in Figure 11B even when the cover 440 is locked in its closed position.

The use of the home theater signal distribution panel 426 represented in Figures 11A-C provides numerous advantages not previously available in the industry. For example, the home theater signal distribution panel provides a neat, clean, efficient, and compact apparatus for interconnecting the components of a home theater system. Other advantages include: Avoidance of damage to cables and cable connectors when loose cables are left protruding from a wall; Avoidance of unclear cable labeling schemes; Avoidance of unsightly jumbled balls of cables; Uncomplicated integration with other electronic signals present in the building; and, Quick connection between audio/visual equipment when new equipment is installed or old equipment is rearranged. All of the forgoing provides benefits which have hitherto been unavailable, particularly in a residential dwelling.

In view of the forgoing, it will be appreciated that one aspect of the present invention provides an electronic information interface which interfaces a plurality of information signals received over a variety of media at a residential or commercial structure and interfaces those information signals to a common protocol which can be recognized by the information utilizing devices in the residential or commercial structure. Furthermore, the present invention also provides an electronic information interface which is configurable to be used with numerous different types of information utilization devices which are present in a residential or commercial structure and which is capable of bidirectional information transfer. Moreover, the present invention also provides an electronic information interface which can be programmed from a remote location such as from a utility provider central office and an interface which is modular and can be easily expanded when desired. The present invention also provides an electronic information interface which can receive information conveyed via a variety of different media and convert the information from any of a variety of protocols to a common protocol .

In accordance with another aspect of the present invention, an electronic information distribution system for use in a structure is provided. The electronic information distribution system is flexible and can be adapted for use with electronic information signals which may be devised in the future. The present invention also provides an electronic information distribution system particularly adapted for use in a residential dwelling which accommodates conveying a number of unidirectional and bidirectional electronic information signals between any number of rooms in the home and which can accommodate the conveying of a variety of electronic information signals from a number of sources to one or more rooms in a home as well as between rooms in a home. Even further, the present invention provides an information distribution system which can selectively convey one or more of a plurality of video, audio, and data information signals between a central location in a building and one or more rooms in the building and which can convey wide bandwidth electronic information signals to and from any number of rooms in the home. It will be further appreciated that the present invention is particularly well adapted for integration into a home automation system, such as home automation systems based upon the industry standards referred to herein as CEBus LonWorks, SMART HOUSE, and any other promulgated or proprietary standard.

In accordance with another aspect of the present invention, an electronic information interface is provided which interfaces a plurality of information signals received over a variety of media at a residential or commercial structure and interfaces those information signals to a common protocol which can be recognized by the information utilizing devices in the residential or commercial structure. The present invention also provides an electronic information interface which is configurable to be used with numerous different types of information utilization devices which are present in a residential or commercial structure and which is capable of bidirectional information transfer. Furthermore, the present invention also provides an electronic information interface which can be programmed from a remote location such as from a utility provider central office and which is modular and can be easily expanded when desired. The present invention also provides an electronic information interface which can receive information conveyed via a variety of different media and convert the information from any of a variety of protocols to a common protocol. The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description.

What is claimed is:

Claims

1. An apparatus for installing a plurality of communication cables in a wall, the wall comprising at least one sheet of wall board having a mounting hole formed therein and each communication cable being terminated in a connector, the apparatus comprising: mounting means for providing a mounting location at the mounting hole formed in the wall board, the mounting means being located in a first plane substantially parallel to the wall board; capturing means for capturing and holding each of the connectors terminating the communications cables in a second plane such that the connectors held therein are directed away from the first plane; covering means for concealing the capturing means and the mounting means, the covering means comprising a first side, a second side, and a plurality of apertures, each of the apertures positioned to closely receive, from its second side, one connector held by the capturing means; and means for securing the capturing means and the covering means to the mounting means such that the connectors are held in a corresponding aperture in the covering means and are positioned to allow a cable to be attached to and removed from the connectors.

2. An apparatus for installing a plurality of communication cables in a wall as defined in claim 1 wherein the mounting means comprises: a frame having an open center; a plurality of formable members, each of the formable members being adapted to bend around the wall board and exert pressure on a second side of the wall board; and means for exerting pressure on a first side of the wall board to prevent the frame from passing through hole in the wall board.

3. An apparatus for installing a plurality of communication cables in a wall as defined in claim 1 wherein the capturing means comprises a first portion of a planar member having a plurality of rectangular openings formed therein, and wherein the means for securing comprises a bore formed in a second portion of the planar member, the first portion of the planar member being offset from the second portion of the planar member.

4. An apparatus for installing a plurality of communication cables in a wall as defined in claim 1 wherein the covering means comprises : a planar member; a first aperture formed in the planar member, the first aperture having a size and a shape to accommodate access to a wiring device therethrough; a second aperture formed in the planar member, the second aperture having a size and a shape to accommodate one of the connectors projecting therein; a third aperture formed in the planar member, the third aperture having a shape and a size to accommodate another one of the connectors projecting therein; and wherein the means for securing comprises a pair of bores formed in the planar member.

5. An apparatus for installing a plurality of communication cables in a wall as defined in claim 1 further comprising a template, the template providing a guide when cutting the hole in the wall .

6. A method for installing a plurality of communication cables in a wall adjacent to an electrical box attached to a building member, each communication cable being terminated in a connector, the method comprising the steps of: releasably attaching the communications cables to a point so that at least the connectors are positioned some distance from the location the communication cables are to be installed in the wall; positioning a template in relation to the electrical box, the template guiding the cutting of a hole in a sheet of wall board at which to install the communication cables; cutting a hole in the sheet of wall board in accordance with the template; retrieving the communication cables through the hole in the sheet of wall board; attaching a mounting frame in the hole adjacent to the electrical box; attaching the connectors to a capture plate such that the connectors project through the capture plate; securing the capture plate to the mounting frame; positioning a cover plate over the mounting frame and the capture plate, the cover plate having a plurality of apertures formed therein, at least one of the apertures formed to accommodate a wiring device secured to the electrical box and at least two of the apertures positioned and formed to allow at least two of the connectors to project therein and allow access to the connectors and the wiring device; and securing the cover plate over the mounting frame and the capture plate such that the mounting frame and the capture plate are concealed thereby.

7. A method for installing a plurality of communication cables in a wall as defined in claim 6 wherein the step of securing the cover plate comprises the step of securing the cover plate using one type of device selected from the group consisting of screws, magnets, and releasable catches.

8. A method for installing a plurality of communication cables in a wall as defined in claim 6 wherein the step of releasably attaching the communications cables comprises the step of attaching the communication cables to a building member with a hook and loop fastener.

9. A method for installing a plurality of communication cables in a wall as defined in claim 6 wherein the step of positioning a template in relation to the electrical box comprises the step of attaching the template to the electrical box.

10. A method for installing a plurality of communication cables in a wall as defined in claim 6 further comprising the step of painting the wall board before retrieving the communication cables through the hole in the sheet of wall board.

11. An apparatus for adapting a multi-line telephone signal distribution hub for use with one or more telephone lines, the multi-line telephone signal distribution hub comprising: a plurality of twisted pair connectors each including at least two jack conductors; a multi-line telephone connector having a first set of plug conductors and a second set of plug conductors and having a connector receiver portion; and a plurality of interconnecting conductors coupling at least two of the jack conductors each to a respective one of the plug conductors, the apparatus comprising: first means for making physical and electrical contact with the first set of plug conductors; second means for making physical and electrical contact with the second set of plug conductors; third means for electrically coupling all of the first set of plug conductors; fourth means for electrically coupling all of the second set of plug conductors; means for holding the first and second means in contact with the first set of plug conductors and the second set of plug conductors and for making physical connection with the connector receiver portion such that any telephone signal which is presented on one twisted pair connectors appears on the remainder of the twisted pair connectors.

12. An apparatus for adapting a multi-line telephone signal distribution hub for use with one or more telephone lines as defined in claim 11 wherein the plurality of twisted pair connectors comprise a plurality of RJ-xx series jacks and wherein the multi- line telephone connector comprises a fifty position receptacle connector.

13. An apparatus for adapting a multi-line telephone signal distribution hub for use with one or more telephone lines as defined in claim 12 wherein the first means for making physical and electrical contact with the first set of plug conductors comprises a first portion of a fifty position plug connector.

14. An apparatus for adapting a multi-line telephone signal distribution hub for use with one or more telephone lines as defined in claim 13 wherein the second means for making physical and electrical contact with the first set of plug conductors comprises a second portion of the fifty position plug connector.

15.A system for distributing audio signals from a central location to a plurality of discrete zones contained within a structure, the system comprising: first means for presenting a first line level audio signal audio signal at the central location from a first program source, the first means for presenting being accessible from a first direction; second means for presenting a second line level audio signal at the central location from a second program source, the second means for presenting being accessible from the first direction; third means for presenting a third line level audio signal at the central location from a third program source, the third means for presenting being accessible from the first direction; first means for increasing gain of the first line level audio signal and generating a first amplified audio signal, the first means for increasing gain comprising an input, an output, and a gain control all of which are accessible from the first direction; second means for increasing gain of the second line level audio signal and generating a second amplified audio signal, the second means for increasing gain comprising an input, an output, and a gain control all of which are accessible from the first direction; third means for increasing gain of the third line level audio signal and generating a third amplified audio signal, the third means for increasing gain comprising an input, an output, and a gain control all of which are accessible from the first direction and the first, second, and third means for increasing gain being positioned at the central location; first means for selectively dispatching any one of the first, second, or third amplified audio 5 signals to a first zone in the structure, the first means for selectively dispatching comprising at least one connector which is accessible from the first direction; a first visually perceptible zone indication 10 adjacent to the first means for selectively dispatching; second means for selectively dispatching any one of the first, second, or third amplified audio signals to a second zone in the structure, the 15 second means for selectively dispatching comprising at least one connector which is accessible from the first direction; a second visually perceptible zone indication adjacent to the second means for selectively

20 dispatching; third means for selectively dispatching any one of the first, second, or third amplified audio signals to a third zone in the structure, the third means for selectively dispatching comprising at 25 least one connector which is accessible from the first direction; a third visually perceptible zone indication adjacent to the third means for selectively dispatching;

30 fourth means for selectively dispatching any one of the first, second, or third amplified audio signals to a fourth zone in the structure, the fourth means for selectively dispatching comprising at least one connector which is accessible from the 35 first direction, the first, second, third and fourth means for selectively dispatching all being positioned adjacent one another at the central location; and a fourth visually perceptible zone indication adjacent to the fourth means for selectively dispatching such that any one of the first, second or third amplified audio signals can be readily directed to any one of the plurality of zones.

16. A system for distributing audio signals from a central location to a plurality of discrete zones contained within a structure as defined in claim 15 wherein the first, second, and third means for presenting a line level audio signals each comprise a phono jack.

17. A system for distributing audio signals from a central location to a plurality of discrete zones contained within a structure as defined in claim 15 wherein the first program source comprises a tuner, wherein the second program source comprises a compact disc player, and wherein the third program source comprises an audio cassette deck.

18. A system for distributing audio signals from a central location to a plurality of discrete zones contained within a structure as defined in claim 15 wherein the each of the first, second, third, and fourth means for selectively dispatching comprises a pair of banana jacks and a banana jack patch cord.

19. A system for distributing audio signals from a central location to a plurality of discrete zones contained within a structure as defined in claim 15 wherein the each of the first, second, and third amplified audio signals each comprise a first and a second channel.

20. A system for distributing electronic signals within a room equipped for audio and video presentations and having at least first, second, third, and fourth speaker connection locations within the room and at least one wall in the room, the system comprising: a panel located on the wall in the room at a control location, the panel having a first side; a first connector accessible from the first side of the panel; a first visually perceptible speaker location indication adjacent to the first connector on the first side of the panel; means for coupling any signal present at the first connector to the first speaker connection location; a second connector accessible from the first side of the panel; a second visually perceptible speaker location indication adjacent to the second connector on the first side of the panel; means for coupling any signal present at the second connector to the second speaker connection location; a third connector accessible from the first side of the panel; a third visually perceptible speaker location indication adjacent to the third connector on the first side of the panel; means for coupling any signal present at the third connector to the third speaker connection location; a fourth connector accessible from the first side of the panel; a fourth visually perceptible speaker location indication adjacent to the fourth connector on the first side of the panel; means for coupling any signal present at the fourth connector to the fourth speaker connection location; cover means for covering the panel, the cover means having an opened position and a closed position; and access means for allowing cables connected to any of the first, second, third, or fourth connectors to reach audio/visual equipment positioned in the room when the cover is in its closed position such that signals may be conveyed from the audio/visual equipment to the first, second, third, or fourth speaker locations within the room.

21. A system for distributing electronic signals within a room equipped for audio and video presentations as defined in claim 20 wherein the first, second, third, and fourth means for conveying each comprise wiring located in the wall of the room.

22. A system for distributing electronic signals within a room equipped for audio and video presentations as defined in claim 20 wherein the cover means further comprises means for locking the cover in its closed position.

23. A system for distributing electronic signals within a room equipped for audio and video presentations as defined in claim 20 further comprising: a coaxial cable connector; and a twisted pair cable connector.

24. A system for distributing electronic signals within a room equipped for audio and video presentations as defined in claim 20 further comprising: a fifth connector accessible from the first side of the panel; a fifth visually perceptible speaker location indication adjacent to the fifth connector on the first side of the panel; means for coupling any signal present at the fifth connector to a fifth speaker connection location; a sixth connector accessible from the first side of the panel; a sixth visually perceptible speaker location indication adjacent to the sixth connector on the first side of the panel; and means for coupling any signal present at the sixth connector to a sixth speaker connection location.

25. A system for distributing electronic information signals from a node zero location in a residential dwelling to a first room, a second room, a third room, and a fourth room in a residential dwelling, the system comprising: support means for holding a plurality of connectors; means for receiving a first information signal from a source external to the residential dwelling; means for receiving a second information signal from a source external to the residential dwelling; means for receiving a third information signal from a source external to the residential dwelling; a first set of connectors connected to the support means, the first set of connectors including a coaxial cable connector, an optical fiber connector, and a twisted pair connector, the first set of connectors conveying electronic information signals between the node zero location and the first room; a second set of connectors connected to the support means, the second set of connectors including a coaxial cable connector, an optical fiber connector, and a twisted pair connector, the second set of connectors conveying electronic information signals between the node zero location and the second room; a third set of connectors connected to the support means, the third set of connectors including a coaxial cable connector, an optical fiber connector, and a twisted pair connector, the third set of connectors conveying electronic information signals between the node zero location and the third room; a fourth set of connectors connected to the support means, the fourth set of connectors including a coaxial cable connector, an optical fiber connector, and a twisted pair connector, the fourth set of connectors conveying electronic information signals between the node zero location and the fourth room; first interconnection means for communicating the electronic information signals present on the means for receiving a first information signal to any of the first, second, third, or fourth set of connectors; second interconnection means for communicating the electronic information signals present on the means for receiving a second information signal to any of the first, second, third, or fourth set of connectors; third interconnection means for communicating the electronic information signals present on the means for receiving a third information signal to any of the first, second, third, or fourth set of connectors; fourth interconnection means for communicating the electronic information signals present on any of the means for receiving a first, second or third information signal to any of the first, second, third, or fourth set of connectors such that any of the information signals can be conveyed to any of the first, second, third or fourth rooms in the residential dwelling.

26. A system for distributing electronic information signals as defined in claim 25 wherein the means for supporting comprising a front panel and a cabine .

27. A system for distributing electronic information signals as defined in claim 25 wherein the means for receiving a first information signal comprises a coaxial cable.

28. A system for distributing electronic information signals as defined in claim 27 wherein the means for receiving a second information signal comprises a twisted pair cable.

29. A system for distributing electronic information signals as defined in claim 28 wherein the means for receiving a third information signal comprises an optical fiber.

30. A system for distributing electronic information signals as defined in claim 25 wherein the coaxial cable connector comprises an RG6 connector.

31. A system for distributing electronic information signals as defined in claim 25 wherein the twisted pair connector comprises a CAT5 connector.

32. A system for distributing electronic information signals as defined in claim 25 wherein each of the first, second, third, and fourth set of connectors each comprise two coaxial cable connectors, two optical fiber connectors, and two twisted pair connectors.

33. A system for distributing electronic information signals as defined in claim 25 wherein the first interconnection means comprises a length of coaxial cable including a coaxial cable connector positioned at each end thereof.

34. A system for distributing electronic information signals as defined in claim 25 wherein the second interconnection means comprises a length of optical fiber including an optical fiber connector positioned at each end thereof.

35. A system for distributing electronic information signals as defined in claim 25 wherein the third interconnection means comprises a length of twisted pair cable including a twisted pair connector positioned at each end thereof.

36. A residential dwelling including an electronic information distribution system comprising: a residential structure comprising: a first room; a second room; a third room; and a fourth room; a node zero location cited in the residential structure; a first electronic information circuit entering the dwelling and conveying electronic information to the node zero location; a second electronic information circuit entering the dwelling and conveying electronic information to the node zero location; a third electronic information circuit entering the dwelling and conveying electronic information to the node zero location; a first bus comprising a coaxial cable, a plurality of twisted conductors, and a fiber optic cable, the first bus extending from the node zero location to the first room; a second bus comprising a coaxial cable, a plurality of twisted conductors, and a fiber optic cable, the second bus extending from the node zero location to the second room; a third bus comprising a coaxial cable, a plurality of twisted conductors, and a fiber optic cable, the third bus extending from the node zero location to the third room; a fourth bus comprising a coaxial cable, a plurality of twisted conductors, and a fiber optic cable, the fourth bus extending from the node zero location to the fourth room; first dissemination means, cited at the node zero location, for selectively conveying any electronic information present on the first, second, or third electronic circuits to any of the first, second, third or fourth buses; second dissemination means, cited at the node zero location, for selectively conveying any electronic information present on the first, second, or third electronic circuits to any of the first, second, third or fourth buses; third dissemination means, cited at the node zero location, for selectively conveying any electronic information present on the first, second, or third electronic circuits to any of the first, second, third or fourth buses.

37. A residential dwelling including an electronic information distribution system as defined in claim 36 wherein: the first electronic information circuit comprises a coaxial cable; the second electronic information circuit comprises an optical fiber; and the third electronic information circuit comprises a twisted pair cable.

38. A residential dwelling including an electronic information distribution system as defined in claim 36 wherein each of the first, second, third and fourth buses comprise two coaxial cables, two twisted pair cables, and two optical fibers.

39. A residential dwelling including an electronic information distribution system as defined in claim 36 wherein the first, second, third, and fourth dissemination means comprises a length of cable selected from the group consisting of coaxial cable, twisted pair cable and optical fiber cable and connectors attached to each end of the length of cable.

40. An apparatus for presenting electronic information signals from a plurality of electronic information carrying conductors strung within a structure, the apparatus comprising; a plate; means for releasably attaching the plate to an existing electrical box; a first aperture in the plate, the first aperture adapted for receiving a wiring device intended for conveying between 100 and 260 volts AC; a second aperture in the plate, the second aperture adapted for receiving a connector means for receiving any one cable from the group consisting of coaxial cable, twisted pair cable and optical fiber cable; a third aperture in the plate, the third aperture adapted for receiving a connector means for receiving any one cable from the group consisting of coaxial cable, twisted pair cable and optical fiber cable; a fourth aperture in the plate, the fourth aperture adapted for receiving a connector means for receiving a cable from the group consisting of coaxial cable, twisted pair cable and optical fiber cable; frame means for securing the plate thereto; means for securing the plate to the frame means and to the electrical box such that when the frame means is attached to the plate and the plate is attached to the electrical box, the plate forms a cover for both the electrical box and the frame means and any of the coaxial cable, the twisted pair cable, and the optical fiber cable can pass through the frame means and to the second, third, and fourth apertures, respectively, such that electronic information signals carried thereon are presented at connectors held on the plate .

41. An apparatus for presenting electronic information signals from a plurality of electronic information carrying conductors as defined in claim 40 wherein the frame means comprises a perimeter and an open back side .

42. An apparatus for presenting electronic information signals from a plurality of electronic information carrying conductors as defined in claim 40 wherein the means for releasably attaching comprises an adhesive.

43. An apparatus for presenting electronic information signals from a plurality of electronic information carrying conductors as defined in claim 40 wherein each of the connectors are removably received into the apertures.

44. An apparatus for presenting electronic information signals from a plurality of electronic information carrying conductors as defined in claim 40 wherein the means for securing the plate to the frame means and to the electrical box comprises at least one fastener selected from the group consisting of screws and bolts.

45. A device for use in installing cables which convey information signals, the cables being installed within a wall of a building, the device comprising: a frame having a perimeter and a front and back side; an opening on the back side of the frame, the opening comprising substantially the entire back side of the frame; means for receiving at least one attaching device for securing a plate to the frame; and means for attaching the frame to one other member, the other member selected from the group consisting of a structural member within the wall and an electrical box installed in the wall .

46. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices, the apparatus comprising: first input means for receiving a first information signal conveyed on a first medium, the first input signal having a first protocol; second input means for receiving a second input signal conveyed on a second medium, the second input signal having a second protocol; third input means for receiving a third input signal conveyed on a third medium, the third input signal having a third protocol; first means for converting the first input signal from the first protocol to a common protocol signal; second means for converting the second input signal from the second protocol to a common protocol signal; third means for converting the third input signal from the third protocol to a common protocol signal; means for selectively programming the first means for converting, the second means for converting, and the third means for converting such that the input signals are correctly converted to the common protocol; and means for directing the common protocol signal, to an output such that the common protocol signal can be received by the information utilizing devices.

47. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 wherein the first input signal is an analog signal.

48. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 wherein the first input signal is a digital signal.

49. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 further comprising means for distributing information within a structure, the apparatus being located within the structure and the means for directing being connected to the means for distributing.

50. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 further comprising a fiber optic cable port connected to one of the input means selected from the first, second, and third input means.

51. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 further comprising a coaxial cable port connected to one of the input means selected from the first, second, and third input means .

52. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 further comprising a twisted pair cable port connected to one of the input means selected from the first, second, and third input means.

53. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 wherein the first, second, and third means for means for converting comprises at least one digital signal processor.

54. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 53 further comprising a microprocessor.

55. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 further comprising a means for modifying the first information signal which is converted by the first means for converting.

56. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 55 wherein the means for modifying comprises a video line doubler.

57. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 55 wherein the means for modifying comprises a television signal decoder.

58. An apparatus for adapting a plurality of electronic information signals to be received by one or more information utilizing devices as defined in claim 46 further comprising a fiber optic back plane interconnecting the first input means, the second input means, the third input means, the first means for converting, the second means for converting, the third means for converting, and the means for directing.

59. An apparatus for interfacing a plurality of electronic information signals, at least some of the electronic information signals being conveyed via one or more utility lines leading to a structure, the apparatus comprising: first input means for receiving a first electronic information signal conveyed to the structure via a first utility line, the first electronic information signal having a first protocol; means for converting the first electronic information signal from the first protocol to a common protocol; second input means for receiving a second electronic information signal originating within the structure, the second electronic information signal having a second protocol; means for converting the second electronic information signal from the second protocol to a common protocol; and means for outputting the first internal signal and the second internal signal onto a signal conveying bus distributed within the structure.

60. An apparatus for interfacing a plurality of electronic information signals as defined in claim 59 wherein the means for converting comprises a digital signal processor.

61. An apparatus for interfacing a plurality of electronic information signals as defined in claim 59 wherein the first input means comprises a port means selected from a fiber optic port means, a twisted pair port means, and a coaxial cable port means.

62. An apparatus for interfacing a plurality of electronic information signals as defined in claim 59 wherein the first electronic information signal comprises an analog electronic information signal.

63. An apparatus for interfacing a plurality of electronic information signals as defined in claim 59 wherein the first electronic information signal comprises a digital electronic information signal.

64. A method for adapting a plurality of electronic information signals to be received by one or more information utilizing devices, the method comprising the steps of : receiving a first information signal conveyed on a first medium, the first input signal having a first protocol; receiving a second input signal conveyed on a second medium, the second input signal having a second protocol ; receiving a third input signal conveyed on a third medium, the third input signal having a third protocol; converting the first input signal from the first protocol to a common protocol signal; converting the second input signal from the second protocol to a common protocol signal; converting the third input signal from the third protocol to a common protocol signal; directing the common protocol signal to an output such that the common protocol signal can be received by the information utilizing devices.

65. A method as defined in claim 64 wherein the step of selectively programming comprises the step of programming the first means for converting from a remote location.