System for integrating multiple building management and home automation services with multiple multi

专利摘要:
A multi-play single-fiber system is described. The system includes a single fiber for providing services based on one or more of the Global System of Mobile (GSM) Communication, Code Division Multiple Access (CDMA), Worldwide Interoperability for Microwave Access (Wimax), Global Positioning System (GPS) and implemented on one or more of: Asynchronous Transfer Mode (ATM), Time Mu (TDM), Transmission Control Protocol-Internet Protocol (TCP-TP), Radio Frequency (RF), Wavclengtb Division Multiplexing (WDM) or Dense Wavelength Division Multiplexing (SWDM) , and a hardware cable computer programmable device connected to the one fiber to create multiple tunnels within the one fiber and create multiple circuits within the tunnels.
公开号:DK201100040U1
申请号:DK201100040U
申请日:2011-02-28
公开日:2011-06-10
发明作者:Shanker Singh Hari
申请人:Shanker Singh Hari；
IPC主号:

专利说明:

1DK 2011 00040 U3
This invention relates to a system for integrating multiple building management services and home automation services and other services including multiplay services with multiple carrier communications services (wired and wireless) including voice, video and data on active and / or passive optical networks and / or neutral access networks. for network operation.
FIELD OF THE INVENTION
This invention generally relates to infrastructure management services where users are interested in multiple services provided by several separate service providers. In particular, the invention relates to enabling the use of single fibers for the secure provision of many different distinct services to an end consumer or user.
BACKGROUND OF THE INVENTION
This invention relates in particular to property related (including residential, commercial, educational, governmental and mixed use) building management services and similar services to other applications where users are interested in varying services. The services that users need are broadly of three types.
One is the service published by external service providers, such as basic telephony, high-speed Internet, television programs and on-demand multimedia content. There are various competing service providers each with their own special offers to meet the specific needs of users. Not only because of this because of the spread of broadband, various essential services become popular, such as telemedicine, distance education, video chat, social networks, e-newspapers, email, data sharing and personal internet sites etc.
Another type of service is property services ranging from area monitoring system, area security system, access control system, guest identification system, 2 2DK 2011 00040 U3 vehicle management system, emergency call system, public notification system, automatic consumption meter reading and control systems, etc.
In addition to the services mentioned above, there is a growing demand for remote control in the home, remote control of the home, remote monitoring of the home and activation and deactivation of various interior design devices, among other things.
Separate infrastructure for building management services (BMS) including video surveillance (CCTV, Closed Circuit Television), heating, ventilation and air conditioning (HVAC, Heat, Ventilation and Air Conditioning), access control, automated consumption meter reading and control systems, among others, and separately Leading Infrastructure Infrastructure The last piece of Information Communication Technology (ICT) services (dedicated or shared) entails high costs, both for capital and maintenance, for the service providers and the property owner / developer.
Furthermore, by remote monitoring and managing applications (enabled home) by residential use and many different uses for business and other uses) means a greater expense for the end user. With ever-increasing demands for broadband, bandwidth and value-added services, along with the ever-increasing demands of the new age's tech-savvy digital natives, it is desirable to have a solution for merging all services, be it ICT services, building management services, or related housing. the least possible cost.
FIG. 1 depicts the typical multiple infrastructure currently used to meet end-user service requirements. This severely lacks space to accommodate future services. Furthermore, the conventional infrastructure is subject to degradation, many different failures and poor accessibility expressed at uptime. In addition, the typical service infrastructure limits end-user choices regarding future services and service providers, since it is not possible to predict future technology and service providers at the time of development or construction of such infrastructure.
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Furthermore, it is impractical as well as impossible to predict the future of technology. Such multiple infrastructures also involve large sums of money for each service provider in the form of capital and maintenance costs. Such investment by several service providers in multiple parallel infrastructures is recovered from users of such services, making the user fees very high and thus making the entire contractual basis between the service provider and end users uneconomical.
EP 1585258 describes that access streams are handled as carrier-tagged streams through a packet-linked network element that interprets and manipulates tag values associated with traffic-carrying data frames. What is described in EP 1585258 will still require a large investment in infrastructure in order to be able to share resources. Similarly, the service provider according to the patent US 2007/274321 will use Ethernet network, DSLAM, xPON etc. to provide their services using various network parameters and service delivery mechanisms, such as DSL, ADSL, VDSL, xPON, Ethernet, ATM, TDM. In other words, each service provider will provide the service over their own end-to-end infrastructure with their self-weighted mechanisms. This, in turn, involves large infrastructure investments with no or very little choice for end users.
Furthermore, the implementations of the asset / smart / connected housing services such as remote-controlled home automation, remote control of the home, remote monitoring of the home and activation and deactivation of various devices within the housing environment, furthermore, involve additional investments for the end user. In addition, the costs at the individual level of the provision of services and systems are very high. There is also the possibility of conflict in different parameters if multiple service providers need to provide their services over the same infrastructure with their own service delivery approaches.
Therefore, a system is needed to transfer all such existing and future services to one communication infrastructure, where the relationship between many users and many of the respective service providers for the many different services remains intact and where the infrastructure acts as a pure intermediary between the end user and the service provider, enabling end users to select competitive services in terms of quality, delivery and price from various service providers, resulting in significant capital and maintenance costs, reducing delivery costs and enabling end users to enjoy the benefits at lower delivery costs at reduced price levels.
SUMMARY OF THE INVENTION
In view of the above-described problems and deficiencies, as well as several others, various embodiments of this invention provide (1) multiplay service provisioning system, (2) broadband services, high-speed Internet access and television, telephone, wireless communications and similar communications services from multiple service providers. (wired or (3) wireless, using one or more GSM-Global System of Mobile Communication, CDMA-Code Division Multiple Access, Wimax-Worldwide Interoperability for Microwave Access, GPS-Global Positioning System, etc.) - whether they are based on (4) ATM (Asynchronous Transfer Mode), TDM (Time-Division Multiplexing), TCP-IP (Transmission Control Protocol-Intemet Protocol), RF Overlay (Radio Frequency Overlay), WDM (Wavelength Division Multiplexing) or DWDM (Dense Wavelength) Division Multiplexing) using several different light wavelengths on a single fiber, Ethernet and similar, using xPON (any possible passive optical network technology such as ΑΡΟΝ, BPON, GPON, EPON, GEPON) technology and / or RF (Radio Frequency) technology or any combination of one or more of them, at any one point -to-multipoint optical fiber network system on a shared use basis; and (5) shared use of the same optical fiber network system to transmit to and from data and signals - whether TCP-IP, Ethernet, RF Overlay, and the like, primarily intended for use in building management systems, including surveillance systems, CCTV, HVAC, access control, automated consumer meter reading and control systems, among others, and collaborative video surveillance and management applications generally used to enable asset / smart / connected home and value-added services using one or more of GSM, CDMA, Wimax, GPS, Femtocell (Access Point Base Station), Zigbee etc. with the same optical fiber network through ONU (Optical Network Unit) based on TCP-IP, Ethernet, RF Overlay protocols and the like.
In another embodiment, a locally based communication system for providing multiple services is provided by multiple service providers to multiple residents in the local area. The system includes an aggregator to collect the multiple services from the multiple service providers, a splitter to distribute the multiple services to the multiple occupants, and an optical fiber connecting the aggregator to the spreader, wherein the optical fiber receives the multiple services from the aggregator and transmits. them to the sprinter through several built-in service provider-specific, secure tunnels. The transmission is performed in such a way that each of the multiple service providers has a dedicated secure tunnel for performing the multiple services and is not aware of the existence of other secure tunnels dedicated to other service providers. The dedicated secure tunnels associated with each of the multiple service providers are configured to have multiple circuits for transmitting the multiple services to their corresponding multiple occupants.
In yet another embodiment, a service delivery port is implemented with multiple end users. The fiber coming from the assembly equipment and terminating at the service delivery port is configured to create multiple secured media such that each secured medium is connected to at least one of the multiple services delivery port for the multiple services provided by at least one of the multiple service providers. Each of the secured media is also programmed such that each of the service providers is able to manage, configure and manage their respective services independently of other service providers.
BRIEF DESCRIPTION OF THE DRAWINGS
A more complete understanding of the various embodiments of the invention can be obtained by reference to the following detailed description when viewed in the context of the accompanying drawings, in which:
FIG. 1 is a simplified principle diagram of conventional multiple service infrastructure.
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FIG. 2 is another simplified principle diagram of an improvement of the conventional integrated infrastructure infrastructure for neutral access to networks.
FIG. 3 is a further simplified principle diagram for assembly equipment.
FIG. 4 is a simplified block diagram for neutral access to networks for first-sequence IP-based services.
FIG. 5 is a simplified block diagram for neutral access to networks for IP-based services with Miden sequence.
FIG. 6 is a simplified block diagram for neutral access to networks for third-party IP-based services.
FIG. Figure 7 is a simplified block diagram for neutral access to networks for IP sequence services with fourth sequence.
FIG. Figure 8 is a simplified block diagram for neutral access to networks for fifth-sequence IP-based services.
FIG. Figure 9 is a simplified block diagram for neutral access to networks for six-sequence IP-based services.
FIG. 10 is a simplified block diagram for neutral access to networks for seventh-sequence IP-based services.
FIG. 11 is a simplified block diagram of neutral access to networks for IP-based services with eighth sequence.
FIG. 12 is a block diagram of neutral access to networks for RF-based DTH / HITS / CATV services - Sequence 1.
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FIG. 13 is a block diagram of neutral network access for RF-based DTH / HITS / CATV services - Sequence 2.
FIG. 14 is a block diagram of neutral access to networks for GSM / CDMA / Mobile services through common antenna system.
FIG. 15 is a femtocell block diagram based on building solution.
FIG. 16 is an example diagram of the preferred embodiment of the invention.
DESCRIPTION OF THE INVENTION WITH RELATED DRAWINGS
Embodiments of systems of the present invention provide successive connection of VLANs (Virtual Local Area Network) / VCs (Virtual Circuits) / PVC (Permanent Virtual Circuits) / PW (Pseudo Wire) in different OSI (Open Systems Interconnection) layers connected to an optical line termination device (Optical Line Termination Unit, OCT) at one end by dedicating a logical layer connection as input and successive configuration of the output of an Optical NetWork Unit (ONU) for each service provider or property owner as it may be, and then a second logical layer, which dedicates a second logical connection on the first layer for each kind of service from a service provider or property owner, and so on until the successive differentiation is achieved in terms of delivery of service content, whether voice and / or video and / or data while maintaining quality of service (QoS) for the intended class of service is.
By dedicating a few wavelengths to the IP packet based voice, video and data services coming from the OCT mentioned above, embodiments of the systems of the invention also provide successive interconnection of RF signals for various services and service providers on WDM switches at separate wavelengths for routing in a single fiber and subsequently disconnecting and converting back to the desired service (s) or service (s) RF signal at the output port of ONU by sending a command instruction to the intended ONU using EMS software that communicates with the assembly equipment in the control room.
With reference to corpses. 2, a further simplified principle diagram is shown of an improvement of the conventional integrated building infrastructure for neutral access to networks. The system 200 eliminates typical deficiencies and problems encountered in the conventional scenario described in FIG. 1. Input, i.e. supply from all of the many service providers 104, 106, 108, 110, 112, 114, 116, 118 providing various services such as intercom 136, telephones 138 and 140, security systems 142, television 144, video surveillance 148, ends at the device room 202. The device room 202 consists of an OCT 202a and aggregator 202b. In other words, it can be understood that the fiber or any other means of communication (wireless or wired) for several different service providers 104, 106, 108, 110, 112, 114, 116, 118 ends at the aggregator 202b in the apparatus space 202. The aggregator 202b is connected through a single light conductor leading the multiple services, such as intercom 136, telephones 138 and 140, security systems 142, television 144, video surveillance 148, from a variety of service providers 104, 106, 108, 110, 112, 114, 116, 118 over a single fiber optic mediums 210a and 210b. This single fiber optic medium 210a and 210b each reaches ONU 216 through an optical splitter 206 and 208 for distribution purposes as shown at 214. Further, by dedicating a few wavelengths to the IP packet based voice, video and data services provided by the OCT, the present invention also successively interconnects RF signals for various services and service providers on (C / D) WDM switches at separate wavelengths to pass on a single fiber and subsequently disconnect and convert back to the desired service (s) or service provider's RF signal at the output port of the ONU by sending a command instruction to the intended ONU using the "EMS software that communicates with the assembly equipment in the control room.
FIG. 3, FIG. 4 and FIG. 5 forms the basis of the invention and in further drawings according to the description, the invention is explained, including the structure of the invention. The control equipment for several different incompatible infrastructures that were previously used for the provision of consumer services now ends up with the assembly equipment (see Figure 2).
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Referring now to FIG. 3, a simplified principle diagram of assembly equipment 202 is shown in which all the various service providers end their supply of services. As shown in FIG. 3, the provision of various services by the various service providers including but not limited to building management system 302 (security and surveillance), several different tripleplay 304 (voice, video and data), multiple satellite receivers (HIT) 306, direct to housing (DTH) 308 is recorded. , GSM / CDMA-based services 310, assembly equipment 312. One of ordinary skill in the art will also note that tripleplay services 304 are routed over VC / VLAN (Circuit / Local Area Network) over designated wavelength, with all other services 306, 308 and 310 is passed over a predetermined designated wavelength. A single fiber optic medium 320 conducts services 302, 304, 306, 308 and 310 from several different service providers and ends at the assembly equipment 312, to their respective service seekers or subscribers. A service provider endpoint equipment (ONU) implemented on the service search or subscriber site has several discrete ports that are assigned to the service providers concerned of their choice. Furthermore, the one secured optical fiber 320 is configured to collect several different service IP packets received through multiple programmable interface units on the service provider side and configured to deliver the service IP packets to designated destinations via the programmable subscriber interface unit. In addition, the one secure optical fiber 320 has several secure tunnels, which are dedicated separately to each of the multiple service providers, and each of the secure tunnels has several programmable circuits capable of sending distinct IP packets to respective subscribers. Therefore, assembly equipment 312 is used to collect various services including building management services, security and surveillance 302, voice, video and data, tripleplay service 304, DTH direct to housing 308, HITS satellite receivers 306, 3G, Wimax, GSM / CDMA 310 from several different service providers and also internal services such as local video-on-demand, cable TV, automatic meter reading, home automation, remote home monitoring, remote access and other consumer-based IP services. According to various embodiments of the present invention, all of the above services are now provided over a single physical optical fiber medium.
With respect to IP packet based communication technology, the invention of FIG. 3-12 a system for separating the physical communication medium, especially a light conductor, into several different logical media within the light conductor, each capable of conducting different IP services. The logical medium is created over the physical medium as a circuit / VLAN / pseudo line for the respective service providers and the property owner. The progressive sequence of the drawing clearly explains how the IP-based services are configured using the present invention, where the infrastructure merely acts as a neutral network without entering a service provider's service area. Referring to FIG. 4, a simplified block diagram for neutral access to networks for first-sequence IP-based services is shown. As is known in the art, an OSI / ISO architecture has seven main layers, namely physical layer 402, data link layer 404, network layer 406, transport layer 408, session layer 410, presentation layer 412, and application layer 414. The one secure light guide described in our invention uses primarily physical layer 402, data link layer 404, for its configuration and operation, while all other layers 406, 408, 410, 412 and 414 are used by service providers for service delivery and provision. The physical layer 402 comprises a single fiber medium which provides all of the services of the service provider. As shown in FIG. 4, the conventional systems used multiple discrete infrastructures to provide multiple services from distinct service providers or multiple services from the same service provider from user site 416 to service space 418, or vice versa. It led to inefficient use of infrastructure and degradation of resources. The data link layer 404 includes logical separation in the tunnel through circuits, VLANs, pseudo-leads in one secure light guide. In order to maintain the integrity of the service provided by a service provider and to maintain the transparency of the infrastructure between the service provider and the subscribers, tunnels have been created at the data link layer 404 so that quality of service parameters for a service provider are not changed. Using the secure single light guide, it appears that communication between user sites 420 (which has an ONU) and service space 422 (which has OCT) uses only a single fiber and thus avoids wastage of resources.
FIG. 5 is a simplified block diagram for neutral access to networks for IP-based services. The several different OS FISO layers depicted in FIG. 5 is in common use with telecommunications service providers / operators. On physical layer 512, data transfer is via physical media. As explained in the description of FIG. 4, logical separation occurs in the data link layer 512. Improvements made by the present invention to the logic layer 512 make data transfer safe and reliable. At the network layer 11 11 2011 2011 00040 U3 510, routing and congestion management takes place, while the transport layer 508 enables reliable transfer from start to finish. Furthermore, session layer 506 assists in communication application synchronization and host communication. Presentation layer 504 interprets the data in the desired format and application layer 502 assists in providing services at the user's site. In other words, according to the claims of the present invention, FIG. 5 transmits secure single-fiber optic medium data from physical layer 514 to application layer 502 using the logical separation at data link 512, by routing and congestion control for the several different service providers at network layer 510 and transmits the same to transport layer 508.
FIG. 6 is a simplified block diagram for neutral access to networks for third-party IP-based services and describes that the secure single light conductor is used as a medium for the physical layer 602. X-PON technology is used for data link layer 604 and network layer 606 is used. various network measures, ie. DHCP relay, DSCP and QoS. Layers 608, 610, 612 and 614 act in the usual manner.
Referring to FIG. 7, a simplified block diagram for neutral access to networks for fourth-sequence IP-based services is shown, depicting how multiple service providers 702 and 704 using the multiple layers of the single light conductor can reach the end subscriber 706 and end at their local equipment 724 via the circuits 712 , 714 and 716 created in the tunnel 702a by the fiber optic data link layer 710 using the OLT 720 and ONU 722 interface and a logical separation by the data link layer 710. The creation of circuits 712, 714 and 716 within the tunnels 702a and 704a form the core of the invention. In addition, each of the several secure tunnels dedicated separately to each of the multiple service providers, and each of the secure tunnels 702a and 704a with multiple programmable circuits 712, 714 and 716, are capable of sending distinct IP packets to respective subscribers . Further, the light conductor receives multiple services from the aggregator 718 and transmits them through several different built-in service provider-specific secure circuits 712, 714 and 716 such that each of the multiple service providers 702 and 704 has a dedicated secure circuit 702a and 704a to provide the multiple services, such that service provider 702 is unaware of the existence of service provider 704, and vice versa. Furthermore, each service provider 702 and 704 is not aware of the existence of safe circuits dedicated to other service providers.
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Referring to FIG. 8, it is a simplified block diagram for neutral access to networks for IP-based services with fifth sequence. Once the tunnels are created by the data link layer 804, the same is transmitted to respective service providers 818. The created tunnels are secure and retain network resources for the service providers 818. From the network layer 806, service provider 818 provides different services to the subscriber over the circuit thus created. The service provider will also be able to manage / configure and manage the services of its NOC (Network Operations Center) and / or EMS (Element Management Software).
FIG. Figure 9 is a simplified block diagram for neutral access to networks for six-sequence IP-based services. The tunnels created over physical layer 902 and data link layer 904 and passed to service providers 916, 918, 920 and 922 are secure so that one service provider's circuit does not interfere / affect another's circuit. Each circuit has a special identity and is assigned to the service provider with the necessary access to it. The service providers 916, 918, 920 and 922 can then have complete control over the network layer 906, the transport layer 908, the session layer 910, the presentation layer 912 and the application layer 914.
In order to accommodate IP-based services from various service providers in the present invention, a single physical medium fiber (dark) is added, i.e. Layer-1, movement up, at Layer 2, logical separation (dark fiber) is created for the respective service providers. The logical separations occur in the present invention such that the relationship between the service provider and its subscribers is intact. Multiple IP services from several different service providers are provided over a single physical medium which records two wavelengths (one pair of wavelengths), one for upstream, another for downstream, and other RF-based services are provided over subsequent wavelengths. This will become more apparent through further description of the figures. Referring to FIG. 10, it is a simplified block diagram for neutral access to networks for seventh-sequence IP-based services, depicting the security and exclusivity aspects of the inventions. It can be seen that any of the multiple service providers 120, 122, 124 and 126 cannot access the circuit 112, 114, 116 and 118 of any other service provider using the same fiber, and therefore there can be no manipulation, configuration, control of service provider 120, 122, 124 and 126 13 13 2011 20114040 U3 specifications of any other service provider 120, 122, 124 and 126, and any such specification does not alter / modify the quality offered by a service provider 120, 122, 124 and 126 or the respective rights policies.
FIG. 11 is a simplified block diagram of neutral access to networks for eighth-sequence IP-based services and describes that each created tunnel 1102 and 1118 may have multiple service providers 1104, 1106, 1108, 1110 and 1112 providing multiple different services through different circuits created within the dedicated tunnels 1102 and 1118. In addition, visible circuits 1114a, 1114b and 1114c are dedicated service provider 1114, and 1116a, 1116b and 1116c are dedicated service provider 1116. Both dedicated tunnels for service providers 1114 and 1116 are also part of a single user tunnel 11 It can also be seen from FIG. 11, that service provider-specific secure tunnels of service provider 1114 and 1116 have dedicated secure circuits 1114a, 1114b, 1114c and 1116a, 1116b, 1116c, respectively, to provide the multiple services so that each of the service providers 1114 and 1116 is unaware of the existence of any other service provider. Furthermore, each service provider 1114 and 1116 is not aware of the existence of safe circuits dedicated to other service providers.
FIG. 12 is a block diagram of neutral access to networks for RF-based DTH / HITS / CATV services - Sequence 1 and shows implementation of the radio frequency-based DTH 1202 and tripleplay services 1204. Several different RF-based services end at IP / WDM based optical equipment 1206 with optical transmitter 1208. The assembly equipment 1206 is connected and provides the multiple services provided by various service providers 1202 and 1204 with a single fiber optic medium 1214. This one fiber optic medium 1214 is coupled to a splitter 1216 for distribution to several different ONUs 1210. ONU 1210 is capable of to practice multiple wavelength support. From ONU 1210, connectivity is provided to the DTH tuning box 1212. The service providers are assigned respective wavelengths for performing services.
FIG. Figure 13 is a block diagram of neutral access to networks for RF-based DTH / HITS / CATV services - Sequence 2 and shows multiple services 1302a and 1304a associated with multiple service providers 1302 and 1304. A splitter 1308 connected to collection equipment 1310 is also shown.
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Furthermore, FIG. 13 more service providers 1302 and 1304 offering several different services 1302a and 1304a to the subscribers, both of IP and RF type. At ONU 1306, the subscriber can select the preferred service provider from among the various service providers available 1302 and 1304. Based on the selection, RF services 1302a and 1304a may be supplied by the preferred service provider by disabling the optical signal at the wavelength assigned to service provider 1302 and 1304. In the case of IP services, the ports can be assigned to different service providers 1302 and 1304. It should also be noted that the service delivery tunnel of service provider 1302 and 1304 at assembly line 1310 terminates at the network layer device or layer 3 device specific to 1302 and 1304. For service provision, a computer programmable equipment (CPE) is inserted into the endpoint port. The network layer device needs an IP address for service provision that can be automatically obtained through DHCP. Furthermore, it may also be noted that each of the RF tuning boxes 1312 and 1314, which are dedicated service providers 1302 and 1304, have output values configured in themselves for automatic provisioning.
Referring now to FIG. 14 illustrates a block diagram of neutral access to networks for GSM / CDMA / Mobile services through a common antenna system. The figure shows several different service providers 1402 and 1404 offering different services (GSM / CDMA / mobile services) to the subscribers on RF basis. BTS Tower (Base Tranceiver System) 1420 for service providers 1402 and 1404 is connected to the collection equipment 1406, and at ONU 1410, the radio frequency-based mobile service can be split based on the wavelength requirements of a single service provider and which in turn is further connected to another BTS device 1412 This BTS spring unit 1412 is then connected to the power divider 1414, which in turn is connected to common antenna system 1412 which provides the last piece to the subscribers of the services.
FIG. 15 is a block diagram of femtocell based on building solution and shows several different service providers 1502 and 1504 offering different services (GSM / CDMA / mobile services) to the subscribers on IP basis. BTS toe 1506 (Base Transceiver System) for service provider 1502 and 1506 is connected to collecting equipment using a single light conductor. At the gathering equipment 1508, the RF based, transmitted data to the IP based through the 15 15GB 2011 00040 U3 is converted to the optical transceiver 1510, and then sent to the ONU 1514. At the ONU 1514, the fiber or fiber optic is extended to the femtocell 1516 base station, where on the optical fiber is created circuit for each service from service providers 1502 and 1504.
FIG. 16 is a sample diagram of the preferred embodiment of the invention and shows the complete infrastructure of the building management services and security and monitoring servers 1602 and 1604 connected to the assembly equipment 1606 connected to the ONU 1612 via a single light conductor. From ONU 1612, services are provided to the end subscriber at 1622. Also connected to ONU are various control means, such as automation and control equipment 1614, access control equipment 1620, HVAC control 1616, power control 1618, etc.
As shown in FIG. 2, 3, 4, 15 and 16, the separation of several different RF based services is achieved with a WDM coupler of the assembly equipment. Each service is provided over a wavelength. The WDM coupler provides several different RF based services at different wavelengths with each RF service provided over a separate wavelength. These several different wavelengths are then decoded at the user end and service delivery is done through the ONT. It supports several different wavelength channels through which different services from different service providers are provided. The fiber architecture constructed for the invention is a point-to-1-point or point-to-multipoint network in which the recommended fiber components between the utility room and each dwelling are passive in nature for greater reliability and easier installation, although any active component can also be used. such as optical amplifier or repeater, wavelength / forward or return injector. The fiber component used to operate multiple homes with a single fiber is an optical splitter. The same optical splitter can serve several other establishments nearby. Each output fiber strand of the splitter reaches each dwelling in the few-fiber complex dedicated common areas for consumer services.
Furthermore, as can be seen from FIG. 2, 12, 15 and 16, the ONU of each dwelling is connected to the fiber that enters the dwelling to enable the full range of services running over the fiber. Each ONU is able to provide IP based and RF based services inside the home. The service from the service provider in question is distributed over a wavelength from 16 DK 2011 00040 U3 The OCT reaches the ONU and is not distributed through the terminal equipment of the service provider concerned or the residential gateway (RG). The service provider RG is a network layer device capable of decoding the services encapsulated in the VLAN / VC / pseudo line and delivering them to the user equipment such as STB, TV, portable, telephone. 5 The ONU enables the provision of TDM services and wireless mobility, including GSM / CDMA / WiFI and home automation at Zigbee.
Furthermore, an ONU is dedicated to common areas for providing consumer services such as building management services, prepaid power, security and monitoring, 10 GSM / CDMA / WiFi, advertising system and various other operating systems.
The terminal equipment for the above services is connected to the ONU that establishes communication with their respective servers for management, administration and configuration. To strengthen the mobility service-GSM / CDMA in the building, the common antenna is also connected to the ONU. To provide better management, management and to facilitate the provision of 15 services from multiple service providers, a network layer management software has been implemented to improve transparency in the operation, monitoring and provision of services by respective service providers. The management software provides an additional layer of manageability, enabling the administrator to manage, manage and monitor ONT-CPE, its service-related and service-provider-related information.

权利要求:
Claims (5)
[1]
A locally based communication system (200) for providing multiple services (136, 138) provided by multiple service providers (106, 108) to multiple residents of the local area, comprising: - an aggregator (202a) for assembling the multiple services ( 136, 138) from the plurality of service providers (106, 108), - a splitter (206) for distributing the plurality of services to the plurality of residents, - an optical fiber (210a) connecting the aggregator to the splitter (206), wherein optical fiber (210a) receives the multiple services from the aggregator (202a) and sends them to the splitter (206) through several different embedded service provider-specific, secure tunnels such that each of the multiple service providers (106, 108) has a dedicated secure tunnel (702a) to provide the multiple services and is unaware of the existence of other secure tunnels dedicated to others by the service providers (106, 108), which dedicated secure tunnels (702a) associated with each of the multiple service providers (106 , 108) are configured to have several different circuits (712) to transmit the multiple services to their corresponding multiple occupants.
[2]
A communication system for providing several different IP service packets to a destination via a secure optical fiber (210a), comprising: - an infrastructure of several different service providers (702, 704) providing several different IP packets for multiple destinations (706 ), each destination having a programmable interface unit (724) on the resident side connected to multiple programmable interface units (720, 722) on the service provider side via a single secure optical fiber (210a), with the one secured optical fiber (210a) configured to collect multiple service IP packets received via multiple programmable interface units on the service provider side (720, 722) and configured to deliver service IP packets to designated destinations (706) via the programmable interface unit (724) on the resident side, optical fiber (210a) has several secure tunnels (702a, 704a) which are dedicated separately to each of the multiple service providers you (702, 704) and each of the secure 18 18DK 2011 00040 U3 tunnels (702a, 704a) has several programmable circuits (712, 714) capable of sending distinct service IP packets.
[3]
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DK 2011 00040 U3 Virtual circuit for each service provider

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FIG. 13 Release line DK 2011 00040 U3

3. Integrated communications infrastructure system for the transport of multiple citizen administration services provided by multiple service providers to multiple end users, the system comprising: - a collection device for the collection of multiple citizen management services provided by the multiple service providers, - a service delivery port implemented by multiple end users, and - an optical fiber, comes from the assembly equipment and terminates at the service delivery port, which optical fiber is configured to create multiple secured media such that each secured medium is connected to at least one of the delivery port for on-and-off transfer of the multiple citizen administration services provided by at least one of the multiple service providers in which each of the secured media is programmed such that each of the service providers is able to manage, configure and manage their respective services independently of other service providers.
[4]
The system of claim 3, wherein the citizen management services consist of one or more of building management services, building automation services, security services, surveillance services, home automation and home management services, services implemented by wired and wireless voice, video and data services, based on either Internet protocol (IP) ) or radio frequency (RF) based service.
The system of claim 4, wherein the services are implemented on one or more of wired and wireless services with voice, video and data.
The system of claim 3, wherein the citizen management services consist of payment information, information collection, information sharing, audio broadcasting, video broadcasting based at least in part on: Internet Protocol (IP), Time Division Multiplexing (TDM), Asynchronous Transfer Mode (ATM), Voice over IP (VoIP) or Radio Frequency (RF). DK 2011 00040 U3 19
The system of claim 3, wherein each of the plurality of different service providers controls, configures and manages their respective services independently of other service providers.
8. Multi-play single-fiber system comprising: - a single fiber for providing services based on one or more of the Global System of Mobile (GSM) Communioation, Code Division Multiple Access (CDMA), Worldwide Interoperability for Microwave Access (Wimax), Global Positioning System (GPS), and implemented on one or more of: Asynchronous Transfer Mode (ATM), Time-Division
Multiplexing (TDM), Transmission Control Protocol-Internet Protocol (TCP-IP), Radio Frequency (RF), Wavelength Division Multiplexing (WDM) or Dense Wavelength Division Multiplexing (SWDM), and - a hardware-coupled computer programmable device connected to one fiber for creating multiple tunnels inside the one fiber and creating multiple circuits inside the tunnels. 15 DK 2011 00040 U3 p

d 11. DK 2011 00040 U3

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[5]
5 é u_ o "T DK 2011 00040 U3 Triplepfay Service Provider

DK 2011 00040 U3 1408

1614 1620

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US20110158649A1|2011-06-30|

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PE20110868A1|2011-12-03|

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UA65354U|2011-12-12|

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EA201170254A1|2011-08-30|

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WO2010035280A1|2010-04-01|

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CR20110108A|2012-12-18|

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CL2011000443A1|2011-10-07|

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AP2011005574A0|2011-02-28|

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JP2012501149A|2012-01-12|

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FIU20110090U0|2011-03-11|

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AU2009297982A1|2010-04-01|

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法律状态:
2016-03-29| UBP| Utility model lapsed|Effective date: 20150831 |

优先权:

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IN2046DE2008|2008-08-29|

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PCT/IN2009/000475|WO2010035280A1|2008-08-29|2009-08-31|Integrating plurality of building management services and home automation services with plurality of multi-play services on neutral access network operation basis|

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