CN103329482B - For electrical management device and the method for distributing antenna system medium-long range antenna element - Google Patents

For electrical management device and the method for distributing antenna system medium-long range antenna element Download PDF

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Publication number
CN103329482B
CN103329482B CN201180053270.3A CN201180053270A CN103329482B CN 103329482 B CN103329482 B CN 103329482B CN 201180053270 A CN201180053270 A CN 201180053270A CN 103329482 B CN103329482 B CN 103329482B
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China
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rau
power
module
power supply
supply port
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CN201180053270.3A
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CN103329482A (en
Inventor
克里斯蒂安·海德勒
乔纳森·R·赫尔
杰西卡·乔伊·凯季奥劳
迈克尔·索尔
沃尔夫冈·施韦克
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Corning Research and Development Corp
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CCS Technology Inc
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L12/00Data switching networks
    • H04L12/02Details
    • H04L12/10Current supply arrangements
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W88/00Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
    • H04W88/08Access point devices
    • H04W88/085Access point devices with remote components

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Mobile Radio Communication Systems (AREA)
  • Remote Monitoring And Control Of Power-Distribution Networks (AREA)

Abstract

The execution mode disclosed in embodiment comprises the electrical management for the remote antenna unit (RAU) in distributing antenna system, and relevant apparatus, system, method and computer-readable media.The operation required electric power being configured to the RAU powered to multiple module and multiple device may exceed the obtainable electric power of described RAU, and electrical management can carry out for this RAU.Such as, described RAU can be configured to comprise power consumption RAU module, to provide the service relevant to distributing antenna system.Again such as, described RAU can be configured to by the power supply port in described RAU externally power consumer apparatus electric power is provided.According to the configuration of described RAU, described power consumption RAU module and/or the electric power required for described outside power consumer apparatus may exceed the electric power that can obtain at described RAU place.In this example, the electric power that can obtain at described RAU place can distribute to described power consumption module and device based on the priority of the service that need be provided by described RAU.

Description

For electrical management device and the method for distributing antenna system medium-long range antenna element
Prioity claim
Subject application is the U.S. Provisional Application case the 61/392nd of " PowerManagementforRemoteAntennaUnitsinDistributedAntenna Systems " according to the title of Patent Law request submission on October 13rd, 2010, the benefit of priority of No. 687, the content of this application case is the foundation of this paper and is incorporated herein in full by reference.
Related application
Subject application and the attorney docket PCT international application case that to be the title of HI10-079 be " LocalPowerManagementforRemoteAntennaUnitsinDistributedAn tennaSystems " is relevant, this PCT international application case and subject application are being applied on the same day simultaneously, the title of subject application request submission on October 13rd, 2010 is the U.S. Provisional Application case the 61/392nd of " LocalPowerManagementforRemoteAntennaUnitsinDistributedAn tennaSystems ", the priority of No. 660, two application cases are incorporated herein by reference in full.
Subject application also with the U.S. Provisional Application case the 61/330th that the title submitted on May 2nd, 2010 is " ProvidingDigitalDataServicesinOpticalFiber-BasedDistribu tedRadioFrequency (RF) CommunicationsSystems; andRelatedComponentsandMethods ", be correlated with for No. 386, this application case is incorporated herein by reference in full.
Subject application also with the U.S. patent application case the 12/892nd that the title submitted on September 28th, 2010 is " ProvidingDigitalDataServicesinOpticalFiber-BasedDistribu tedRadioFrequency (RF) CommunicationsSystems; andRelatedComponentsandMethods ", be correlated with for No. 424, this application case is incorporated herein by reference in full.
Subject application also with the U.S. Provisional Application case the 61/230th that the title submitted on July 31st, 2009 is " OpticalFiber-BasedDistributedAntennaSystems; Components; andRelatedMethodsforCalibrationThereof ", be correlated with for No. 463, this application case is incorporated herein by reference in full.
Subject application also with the U.S. Provisional Application case the 61/230th that the title submitted on July 31st, 2009 is " OpticalFiber-BasedDistributedAntennaSystems; Components; andRelatedMethodsforMonitoringtheStatusThereof ", be correlated with for No. 472, this application case is incorporated herein by reference in full.
Technical field
Technology of the present invention relates to the electrical management for the remote antenna unit in distributing antenna system, and described distributing antenna system is used for radio frequency (RF) signal to distribute to described remote antenna unit.
Background technology
Wireless communication technology is fast-developing, meanwhile, also growing to the demand of high-speed mobile data communication.Such as, so-called " Wireless Fidelity " or " WiFi " system and WLAN (WLAN) have been deployed in (such as, cafe, airport, library etc.) in many dissimilar regions.Distributing antenna system communicates with the wireless device being called " client (client) ", and described " client " must belong in wireless range or " cell coverage area ", thus can communicate with access point apparatus.
A kind of method for disposing distributing antenna system relates to the use of radio frequency (RF) antenna coverage areas (also referred to as " antenna coverage areas ").Described antenna coverage areas is provided by the remote antenna unit in distributing antenna system.Such as, the radius of antenna coverage areas that remote antenna unit provides can in several meters of scopes to 20 (20) rice.If the antenna coverage areas provided covers a comparatively zonule separately, in so each antenna coverage areas, usually only has several user (client).The RF amount of bandwidth shared between wireless system users can be allowed like this to reduce to minimum.May need to provide antenna coverage areas in building or other facilities, thus provide the access of indoor distributed antenna system for the client in described building or facility.In addition, also may need to adopt optical fiber to distribute RF signal of communication, thus form the distributing antenna system based on optical fiber.Distribute RF signal of communication via optical fiber and can comprise light-carried wireless electricity (RoF) distribution.The advantage of optical fiber comprises the bandwidth of increase.
Remote antenna unit can comprise power consuming circuit and relate to other assemblies processed RF signal of communication.Such as, can comprise based on remote antenna unit set in the distributing antenna system of optical fiber and need electric power just operable electric light (E/O) transducer and photoelectricity (O/E) transducer.Down link light RF signal of communication is converted to down link electricity RF signal of communication by E/O transducer, and O/E transducer converts uplink electrical RF signal of communication to uplink optical RF signal of communication.Other power consumption components can be comprised in remote antenna unit.Local power supply can be arranged on remote antenna unit place, to supply electric power to the power consumption components in remote antenna unit.Or, in order to avoid arranging local power supply, can be arranged through be routed to remote antenna unit power line to provide the remote power supply of electric power.Described power line can be arranged in separate cable, or can be bundled in compound cable together with the order wire being routed to remote antenna unit.
Focus on, the electric power of q.s is supplied to remote antenna unit, so that suitably for the power consumption components be arranged in remote antenna unit is powered.Otherwise the power consumption components in remote antenna unit may carry out faulty operation, and may not provide required service for distributing antenna system.If be provided with multiple power consumption components in remote antenna unit, the electric power being so supplied to remote antenna unit will give described multiple assembly.In the case, another focuses on, and will manage electric power, to provide enough electric power for each power consumption components.
Summary of the invention
The execution mode disclosed in embodiment comprises the electrical management for the remote antenna unit (RAU) in distributing antenna system, and relevant apparatus, system, method and computer-readable media.Radio frequency (RF) signal of communication can be distributed to multiple RAU by described distributing antenna system, so that by described RF communication signal transmissions to client terminal device.As limiting examples, distributing antenna system can be the distributing antenna system based on optical fiber.The operation required electric power being configured to the RAU powered to multiple module and multiple device may exceed the obtainable electric power of described RAU, and electrical management can carry out for this RAU.Such as, RAU can be configured to comprise power consumption RAU module, to provide the service relevant to distributing antenna system.Again such as, RAU can be configured to by the power supply port in RAU externally power consumer apparatus electric power is provided.According to the configuration of RAU, described power consumption RAU module and/or the electric power required for described outside power consumer apparatus may exceed the electric power that can obtain at RAU place.In this example, the electric power that can obtain at RAU place can distribute to described power consumption module and device based on the priority of the service that need be provided by described RAU.
In one embodiment, provide a kind of electrical management device, the electric power that described electrical management device is used for the RAU place in distributing antenna system consumes carries out telemanagement.Described electrical management device comprises: remote controllers, and described remote controllers are coupled at least one RAU by correspondence, and at least one outside power consumer apparatus that described RAU is configured to being connected at least one power supply port provides electric power.Described remote controllers are configured to communicate with at least one RAU described, to determine the obtained power budget of at least one power supply port described.Described remote controllers are also configured to the obtained power budget of at least one power supply port described at least one RAU described to be transferred at least one RAU described.
In another embodiment, a kind of method that electric power for consuming the RAU place in distributing antenna system carries out telemanagement is provided.Described method comprises following steps: communicate the obtained power budget determining at least one port of powering with at least one RAU, and at least one outside power consumer apparatus that described RAU is configured to being connected at least one power supply port described provides electric power.Described method also comprises following steps: the obtained power budget of at least one power supply port described at least one RAU described is transferred at least one RAU described.
In another embodiment, a kind of computer-readable media is provided.Described computer-readable media stores one or more program, described one or more program comprises instruction, when being arranged in distributing antenna system and the remote controllers being positioned at the remote location place of RAU perform described instruction, described instruction makes described remote controllers: communicate the obtained power budget determining at least one port of powering be arranged at least one RAU described with at least one RAU be arranged in distributing antenna system, and at least one outside power consumer apparatus that described RAU is configured to being connected at least one power supply port described provides electric power.Described instruction makes described remote controllers further: the obtained power budget of at least one power supply port described at least one RAU described is transferred at least one RAU described.
In another embodiment, a kind of RAU for distributing antenna system is provided.Described RAU comprises at least one power consumption RAU module.As limiting examples, described at least one power consumption RAU module can be made up of at least one item in following item: the RF communication module being configured to provide RF communication service; And be configured to the DDS module that digital data service (DDS) is provided.Described RAU comprises further: at least one port of powering, and at least one outside power consumer apparatus that described power supply port is configured to being connected at least one power supply port described provides electric power.Described RAU comprises further: controller, and described controller is configured to the obtained power budget receiving at least one power supply port described from the remote controllers distributing antenna system.Described RAU controller is configured to further: be enough to when being connected to that described at least one power supply port described, at least one outside power consumer apparatus is powered, at least one power supply port described provides electric power in the described power budget that obtains.
In another embodiment, a kind of method managed for the electric power consumed the RAU place in distributing antenna system is provided.Said method comprising the steps of: the obtained power budget receiving at least one power supply port, described power supply port is configured to based on the electric power needed at least one power consumption RAU module, provides electric power at least one the outside power consumer apparatus being connected at least one power supply port described.As limiting examples, described at least one power consumption RAU module can be made up of at least one item in following item: the RF communication module being configured to provide RF communication service; And be configured to the DDS module that digital data service (DDS) is provided.Described method is further comprising the steps: be enough to when being connected to that described at least one power supply port described, at least one outside power consumer apparatus is powered, at least one power supply port described provides electric power when can obtain power budget.
In another embodiment, a kind of computer-readable media is provided.Described computer-readable media stores one or more program, described one or more program comprises instruction, when the RAU controller at least one RAU be arranged in distributing antenna system performs described instruction, described instruction makes described RAU controller: the obtained power budget receiving at least one power supply port from remote controllers, at least one power supply port described is arranged in the RAU being arranged on distributing antenna system, described RAU is configured to based on the electric power needed at least one power consumption RAU module, electric power is provided at least one the outside power consumer apparatus being connected at least one power supply port described.Described instruction makes described RAU controller further: be enough to when being connected to that described at least one power supply port described, at least one outside power consumer apparatus is powered, at least one power supply port described provides electric power when can obtain power budget.
Should be understood that in large volume description above and embodiment hereafter and propose multiple execution mode, the general view or framework of understanding the present invention's essence and characteristic and intention is offered help.
Being included by accompanying drawing is to understand the present invention further, and these accompanying drawings to be merged in this specification and to constitute the part of this specification.Accompanying drawing illustrates multiple execution mode, and is aided with description to be explained with operation the principle of disclosed concept.
Accompanying drawing explanation
Fig. 1 is the schematic diagram of example distributed antenna system;
Fig. 2 is the more detailed schematic diagram of exemplary head end equipment and remote antenna unit (RAU), and described headend and RAU can dispose in distributing antenna system in FIG;
Fig. 3 is the diagrammatic cross-section fragmentary of exemplary building foundation facility, can adopt the distributing antenna system in Fig. 1 in the facility of described building foundation;
Fig. 4 is the schematic diagram of another example distributed antenna system;
Fig. 5 is the schematic diagram of the illustrative embodiments providing digital data service to the RAU in distributing antenna system;
Fig. 6 is the schematic diagram being configured to the exemplary RAU with power consumption components and Remote Expansion unit, and described power consumption components is used for providing radio frequency (RF) communication service, digital data service and external power being supplied to digital data service device;
Fig. 7 is used to the exemplary priority scheme that the power consumption components that may be present in RAU provides electric power;
Fig. 8 is the schematic diagram of the exemplary RAU comprising remote power management, and described remote power management is used for managing the electric power being supplied to inside power consumption module and the outside power consumption module being connected to described RAU;
Fig. 9 be a diagram that the flow chart of the exemplary remote electrical management process that the controller in Fig. 8 provides, and described remote power management process is used for carrying out remote power management at RAU place;
Figure 10 be a diagram that the flow chart of the exemplary power management process that RAU provides, and described electrical management process is used at initial phase and the electric power managing RAU place when the configuration of RAU is changed;
Figure 11 be a diagram that the flow chart of the exemplary power management process that RAU provides, and the electric power that described electrical management process is used for being supplied to power supply port set in RAU manages;
Figure 12 can be arranged in RAU to provide exemplary digital data service (DDS) module of digital data service at RAU place; And
Figure 13 can be included in the general illustration schematic diagram that head end controls the exemplary computer system in (HEC), described exemplary computer system for performing the instruction from exemplary computer readable media, to perform power management capabilities to RAU.
Embodiment
Now with detailed reference to execution mode, the example of these execution modes illustrates in the accompanying drawings, described shown in the drawings of some not all embodiments.In fact, described concept multi-formly can be implemented according to many, and should not be construed as and restrict in this article; On the contrary, the object of these execution modes is provided to be to make the present invention meet applicable legal requiremnt.In every place, identical reference number will be used in reference to identical assembly or part.
The execution mode disclosed in embodiment comprises the electrical management for remote antenna unit (RAU) one or more in distributing antenna system, and relevant apparatus, system, method and computer-readable media.Radio frequency (RF) signal of communication can be distributed to RAU by described distributing antenna system, so that by described RF communication signal transmissions to client terminal device.As a limiting examples, distributing antenna system can be the distributing antenna system based on optical fiber.The operation required electric power being configured to the RAU powered to multiple module and multiple device may exceed the obtainable electric power of RAU, and electrical management can carry out for this RAU.Such as, RAU can be configured to comprise power consumption RAU module, to provide the service relevant to distributing antenna system.Again such as, RAU can be configured to by the power supply port in RAU externally power consumer apparatus electric power is provided.According to the configuration of RAU, power consumption RAU module and/or the electric power required for outside power consumer apparatus may exceed the electric power that can obtain at RAU place.In this example, the electric power that can obtain at RAU place can distribute to power consumption module and device based on the priority of the service that need be provided by RAU.
From Fig. 5 place, discuss for the electrical management of RAU set in distributing antenna system and associated component and method, before this, provide Fig. 1 to Fig. 4, and hereinafter first will discuss Fig. 1 to Fig. 4.Fig. 1 to Fig. 4 provides the Multi-instance of distributing antenna system, comprises those examples according to described execution mode herein.
Fig. 1 is the schematic diagram of example distributed antenna system.In this embodiment, distributing antenna system is the distributing antenna system 10 based on optical fiber; But the distributing antenna system of other types is also feasible.Distributing antenna system 10 based on optical fiber is configured to form one or more antenna coverage areas, thus sets up with the wireless client device of the RF scope being arranged in described antenna coverage areas and communicate.Distributing antenna system 10 based on optical fiber provides RF communication service (such as, cellular service).In this embodiment, the distributing antenna system 10 based on optical fiber comprises the headend of head-end unit (HEU) 12 form, one or more remote antenna unit (RAU) 14, and HEU12 is coupled light to the optical fiber 16 of RAU14.HEU12 is configured to via the down link electricity RF signal of communication 18D received communication from one or more signal source (such as, network or carrier wave), and provides this type of to communicate for RAU14.HEU12 is also configured to, via uplink electrical RF signal of communication 18U, the communication being received from RAU14 is returned to described one or more signal source.In this embodiment, for this respect, optical fiber 16 comprises: at least one downlink optical fiber 16D, downlink optical fiber 16D are transferred to the signal of RAU14 from HEU12 for carrying; And at least one uplink optical fiber 16U, uplink optical fiber 16U are for carrying the signal transmitting back HEU12 from RAU14.
Distributing antenna system 10 based on optical fiber has can the antenna footprint 20 of cardinal principle centered by RAU14.The antenna footprint 20 of RAU14 forms RF coverage 21.HEU12 is used for performing or facilitate any one in the application of many light-carried wireless electricity (RoF), such as, and the communication of radio-frequency (RF) identification (RFID), WLAN (WLAN) or cell phone service.Be depicted as the client terminal device 24 of (such as) mobile device form in antenna coverage areas 20, client terminal device 24 can be (such as) cell phone.Client terminal device 24 can be any device that can receive RF signal of communication.Client terminal device 24 comprises antenna 26(for receiving and/or send electromagnetism RF signal of communication such as, wireless network card).
Continue with reference to figure 1, in order to via downlink optical fiber 16D by electric RF communication signal transmissions to RAU14, the client terminal device 24, HEU12 be then transferred in the antenna coverage areas 20 formed by RAU14 comprises electric light (E/O) transducer 28.E/O transducer 28 converts down link electricity RF signal of communication 18D to down link light RF signal of communication 22D, and signal of communication 22D will transmit via downlink optical fiber 16D.RAU14 comprises photoelectricity (O/E) transducer 30, O/E transducer 30 is for changing telegram in reply RF signal of communication by received down link light RF signal of communication 22D, and the antenna 32 by RAU14 is wirelessly transmitted to the client terminal device 24 being arranged in antenna coverage areas 20 by described electric RF signal of communication.
Similarly, antenna 32 is also configured to receive wireless RF communication from the client terminal device 24 antenna coverage areas 20.In this respect, antenna 32 receives wireless RF communication from client terminal device 24, and will represent that the electric RF communication signal transmissions of described wireless RF communication is to the E/O transducer 34 in RAU14.E/O transducer 34 converts described electric RF signal of communication to uplink optical RF signal of communication 22U, and signal of communication 22U will transmit via uplink optical fiber 16U.The O/E transducer 36 be arranged in HEU12 converts uplink optical RF signal of communication 22U to uplink electrical RF signal of communication, and described uplink electrical RF signal of communication can transmit back network or other signal sources as uplink electrical RF signal of communication 18U subsequently.HEU12 in this execution mode can not distinguish the position of the client terminal device 24 in this execution mode.Client terminal device 24 can be in the scope of any antenna coverage areas 20 formed by RAU14.
Fig. 2 is the more detailed schematic diagram of the exemplary distributing antenna system 10 based on optical fiber in Fig. 1, and the distributing antenna system 10 based on optical fiber provides electric RF service signal for specific RF service or application.In an illustrative embodiments, HEU12 comprises service unit 37, and service unit 37 provides electric RF service signal in the following manner: transmit (or first regulate transmit again) this type of signal from one or more external network 38 via network link 39.In a specific exemplary embodiments, this comprises: distribute to perform WLAN signal according to the regulation in Institute of Electrical and Electric Engineers (IEEE) 802.11 standard, that is, in the frequency range that 2.4 to 2.5 Gigahertzs (GHz) and 5.0 arrive 6.0GHz, perform WLAN signal to distribute.Any other electric RF communication signal frequency is all feasible.In another illustrative embodiments, service unit 37 provides electric RF service signal by directly generating signal.In another illustrative embodiments, service unit 37 coordinates the transmission of electric RF service signal between the client terminal device 24 in antenna coverage areas 20.
Continue with reference to figure 2, service unit 37 is electrically coupled to E/O transducer 28, E/O transducer 28 from service unit 37 receiving downlink electricity RF signal of communication 18D, and signal of communication 18D is converted to corresponding down link light RF signal of communication 22D.In an illustrative embodiments, E/O transducer 28 comprises the laser being suitable for the enough dynamic ranges of described RoF application transport herein, and optionally comprises the laser driver/amplifier being electrically coupled to described laser.Be applicable to the example of the laser of E/O transducer 28 including (but not limited to) laser diode, distributed Feedback (DFB) laser, Fabry-Perot (Fabry-Perot; FP) laser and Vcsel (VCSEL).
Continue also to comprise with reference to figure 2, HEU12 the O/E transducer 36 being electrically coupled to service unit 37.O/E transducer 36 receiving uplink light RF signal of communication 22U, and signal of communication 22U is converted to corresponding uplink electrical RF signal of communication 18U.In an illustrative embodiments, O/E transducer 36 is photodetectors, or is electrically coupled to the photodetector of linear amplifier.E/O transducer 28 and O/E transducer 36 form " transducer to " 35, as shown in Figure 2.
According to an illustrative embodiments, the service unit 37 in HEU12 can comprise the RF signal of communication conditioner unit 40 for regulating down link electricity RF signal of communication 18D and uplink electrical RF signal of communication 18U respectively.Service unit 37 can comprise the digital signal processing unit (" digital signal processor ") 42 for providing the signal of telecommunication for RF signal of communication conditioner unit 40, and the described signal of telecommunication is modulated onto on RF carrier wave to generate required down link electricity RF signal of communication 18D.Digital signal processor 42 is also configured to process restituted signal, and the solution that described restituted signal is undertaken by RF signal of communication conditioner unit 40 couples of uplink electrical RF signal of communication 18U transfers to provide.Service unit 37 in HEU12 can also comprise: optional head-end unit controller (HEC) 44(or " controller 44 "), controller 44 is for the treatment of data, and actuating logic computing and calculating operation; And memory cell 46, memory cell 46, for storing data, such as, treats the data transmitted via (such as) WLAN or other networks.
Continue to comprise transducer equally to 48 with reference to figure 2, RAU14, transducer comprises O/E transducer 30 and E/O transducer 34 to 48.The down link light RF signal of communication 22D being received from HEU12 is converted back down link electricity RF signal of communication 50D by O/E transducer 30.E/O transducer 34 converts the uplink electrical RF signal of communication 50U being received from client terminal device 24 to uplink optical RF signal of communication 22U, and signal of communication 22U will be transferred to HEU12.O/E transducer 30 and E/O transducer 34 are electrically coupled to antenna 32 via RF signal guide elements 52 such as circulators.RF signal guide element 52 for down link electricity RF signal of communication 50D and uplink electrical RF signal of communication 50U lead, as discussed below.According to an illustrative embodiments, antenna 32 can comprise the antenna of any type, including (but not limited to) one or more paster antenna, the title submitted to such as on August 16th, 2006 is the U.S. patent application case the 11/504th of " Radio-over-FiberTransponderWithADual-BandPatchAntennaSys tem ", the title submitted in No. 999 and on June 12nd, 2006 is the U.S. patent application case the 11/451st of " CentralizedOpticalFiber-basedWirelessPicocellularSystems andMethods ", disclosed in No. 553, two application cases are incorporated herein all by reference in full.
Continue with reference to figure 2, the distributing antenna system 10 based on optical fiber also comprises the power supply unit 54 providing electric power signal 56.Power supply unit 54 is electrically coupled to HEU12, to power for the consuming components in HEU12.In an illustrative embodiments, power line 58 arrives RAU14 by HEU12, unless so that for transducer are the passive devices such as circulator to the O/E transducer 30 in 48 and E/O transducer 34, optional RF signal guide element 52(RF signal guide element 52) and any other set consuming components power.In an illustrative embodiments, power line 58 comprises two wires 60 and 62, and electric wire 60 and 62 carries univoltage and is electrically coupled to the DC electric power converter 64 at RAU14 place.DC electric power converter 64 is electrically coupled to transducer to the O/E transducer 30 in 48 and E/O transducer 34, and the voltage of electric power signal 56 or level is changed into the power level needed for power consumption components in RAU14.In an illustrative embodiments, DC electric power converter 64 is DC/DC electric power converter or AC/DC electric power converter, and this depends on the type of the electric power signal 56 that power line 58 carries.In another illustrative embodiments, power line 58(dotted line) directly extend to RAU14 from power supply unit 54, instead of extend to RAU14 from HEU12 or extend through HEU12.In another illustrative embodiments, power line 58 comprises more than two electric wires and can carry multiple voltage.
In order to exemplarily be shown in the feasible pattern of indoor deployment based on the distributing antenna system of optical fiber further, provide Fig. 3.Fig. 3 adopts the diagrammatic cross-section fragmentary based on the building foundation facility 70 of the distributing antenna system of optical fiber.Described system can be the distributing antenna system 10 based on optical fiber in Fig. 1 and Fig. 2.Any type building of the distributing antenna system 10 based on optical fiber can be disposed in building foundation facility 70 general proxy inside.Such as, as composition graphs 1 before and Fig. 2 discuss, HEU12 is incorporated to by the distributing antenna system 10 based on optical fiber, various types of communication service to be provided to the overlay area in building foundation facility 70.Such as, according to hereafter carried out more detailed discussion, be configured to receive wireless RF communication signal based on the distributing antenna system 10 of optical fiber in this execution mode, and convert described RF signal of communication to RoF signal, described RoF signal will be transferred to multiple RAU14 via optical fiber 16.Can be (such as) indoor distributed antenna system (IDAS) based on the distributing antenna system 10 of optical fiber in this execution mode, to provide wireless service in building foundation facility 70.These wireless signals can comprise cellular service and wireless service, described wireless service such as, the combination of RFID tracking, Wireless Fidelity (WiFi), LAN (LAN), WLAN and above item.
Continue with reference to figure 3, the building foundation facility 70 in this execution mode comprises ground floor (bottom) 72, the second layer 74 and third layer 76.Layer 72,74,76 is served by the HEU12 through Main distribution frames 78, to provide antenna coverage areas 80 in building foundation facility 70.In order to simplicity of illustration, in Fig. 3, illustrate only the ceiling of layer 72,74,76.In the exemplary embodiment, leader cable 82 has many different sections, and these sections are conducive to placing a large amount of RAU14 in building foundation facility 70.Each RAU14 serves again the overlay area of self in antenna coverage areas 80.Leader cable 82 can including (for example) riser cable 84, and riser cable 84 carries all downlink optical fiber 16D and the uplink optical fiber 16U that to extend or lead to HEU12 from HEU12.Riser cable 84 can pass through interconnecting unit (ICU) 85 and carry out route.ICU85 can as a part for the power supply unit 54 in Fig. 2 or independent of power supply unit 54.ICU85 can also be configured to provide electric power via power line 58 to RAU14, as shown in Figure 2 and as discussed above, it is inner that described power line 58 is arranged on array cable 87 or (again such as) tail cable or home-use tether cable, and be assigned to RAU14 by downlink optical fiber 16D and uplink optical fiber 16U.Leader cable 82 can comprise one or more many cables (MC) connector, and described MC connector is used for selected downlink optical fiber 16D and uplink optical fiber 16U and power line to be connected to multifiber cable 86.
Leader cable 82 makes multifiber cable 86 can be assigned in whole building foundation facility 70 (such as, be fixed to ceiling or other area supporteds of each layer 72,74,76), to provide antenna coverage areas 80 for ground floor 72, the second layer 74 and third layer 76.In an illustrative embodiments, HEU12 is positioned at building foundation facility 70 (such as, being arranged in cubicle or control room), and in another illustrative embodiments, HEU12 can be positioned at the remote location place of building foundation facility 70 outside.Base transceiver station (BTS) 88 can be provided by the opposing party, and such as, cellular service provider, BTS88 is connected to HEU12, and can be positioned at same position with HEU12 or be positioned at the remote location place of HEU12.BTS is any station or the signal source that input signal are supplied to HEU12 and can receive inverse signal from HEU12.In typical cellular system, such as, multiple BTS is arranged in multiple remote location place, covers to provide radio telephone.Each BTS serves respective cell, and when mobile client end device enters described community, BTS communicates with described mobile client end device.Each BTS can comprise at least one radio transceiver, thus can communicate with the one or more subscriber units operated in cell associated.Again such as, wireless repeater or two-way amplifier can also be used for replacing BTS to serve respective cell.Or again such as, radio input can be provided by repeater or Pico cell.
In Fig. 1 to Fig. 3 and the distributing antenna system 10 based on optical fiber mentioned above between HEU12 and RAU14, provide point-to-point communication.Each RAU14 communicates with HEU12 with uplink optical fiber pair via different down links, thus provides point-to-point communication.As long as RAU14 is arranged in the distributing antenna system 10 based on optical fiber, RAU14 just from the different down link being connected to HEU12 with uplink optical fiber to being connected.Downlink optical fiber 16U and uplink optical fiber 16D can be arranged in fiber optic cables.Multiple down link and uplink optical fiber to being arranged in fiber optic cables, to serve multiple RAU14 by common light fiber-optic cable.Such as, with reference to figure 3, be arranged on and can obtain service by identical optical fiber 16 to the RAU14 in given layer 72,74,76.In this respect, optical fiber 16 can have multiple node, and at described Nodes, different down links and uplink optical fiber are to being connected to given RAU14.A downlink optical fiber 16 can be set to support multiple channel, each channel uses wavelength division multiplexing (WDM), as the U.S. patent application case the 12/892nd that title is " ProvidingDigitalDataServicesinOpticalFiber-BasedDistribu tedRadioFrequency (RF) CommunicationsSystems; andRelatedComponentsandMethods ", discussing in No. 424, this application case is incorporated herein by reference in full.U.S. patent application case the 12/892nd, further disclose other Alternative Content (WDM and frequency division multiplexing (FDM)) in No. 424, any Alternative Content wherein can be used in any execution mode disclosed herein.
Fig. 4 is the schematic diagram of another example distributed antenna system 90.In this embodiment, the distributing antenna system based on optical fiber that is made up of three master components of distributing antenna system 90.The one or more radio interface 92 (1)-92 (M) being arranged to radio interface module (RIM) form in this execution mode are arranged in HEU94, with receiving downlink electricity RF signal of communication 96 (1)-96 (R) process described signal, then described signal is just converted to down link light RF signal of communication by light.Any process in Fig. 2 described hereinbefore before can comprising the process of down link electricity RF signal of communication 96 (1)-96 (R) in HEU12.Symbol " 1-R " and " 1-M " represent respectively can arrange an arbitrary number described assembly 1-R and described assembly 1-M.According to the more detailed description of hereafter will carry out, HEU94 is configured to receive multiple RIM92 (1)-92 (M) as modular assembly, and in HEU94, described modular assembly can easily obtain installation and removal or replacement.In one embodiment, as an example, HEU94 is configured to support nearly four (4) RIM92 (1)-92 (M).
(namely each RIM92 (1)-92 (M) can through design to support the radio-signal source of particular type or various radio-signal source, multi-frequency), thus improve the configuration flexibility of HEU94 and the distributing antenna system 90 based on optical fiber, to support required radio-signal source.Such as, a RIM92 can be configured to support personal communication service (PCS) radio bands.Another RIM92 can be configured to support 700MHz radio bands.In this example, be configured to support PCS and LTE700 radio bands by comprising these RIM92, HEU94, and distribute RF signal of communication on PCS and LTE700 radio bands.RIM92 can be arranged in the HEU94 supporting any required frequency band, and described frequency band is including (but not limited to) American cellular frequency band, PCS(personal communication service) frequency band, AWS(Advanced Wireless Services) frequency band, 700MHz frequency band, global system for mobile communications (GSM) 900, GSM1800, UMTS.RIM92 can be arranged in the HEU94 supporting any required wireless technology, and described wireless technology is including (but not limited to) CDMA(code division multiple access), CDMA200, lxRTT, EV-DO(Evolution-DataOnly), UMTS(universal mobile telecommunications system), the access of HSPA(high-speed packet), GSM, GPRS(General Packet Radio Service), EDGE(enhanced data gsm environment), TDMA(time division multiple access), LTE(Long Term Evolution), iDEN and CDPD(Cellular Digital Packet Data).
RIM92 can be arranged in the HEU94 supporting any required frequency, described frequency is including (but not limited to) the frequency (824-849MHz in up link and the 869-894MHz on down link) of U.S. FCC and Canada Ministry of Industry, the frequency (1850-1915MHz in up link and the 1930-1995MHz on down link) of U.S. FCC and Canada Ministry of Industry, the frequency (1710-1755MHz in up link and the 2110-2155MHz on down link) of U.S. FCC and Canada Ministry of Industry, the frequency (698-716MHz and 776-787MHz in up link and the 728-746MHz on down link) of U.S. FCC.The frequency (880-915MHz in up link and the 925-960MHz on down link) of European Union R & TTE, the frequency (1710-1785MHz in up link and the 1805-1880MHz on down link) of European Union R & TTE, the frequency (1920-1980MHz in up link and the 2110-2170MHz on down link) of European Union R & TTE, the frequency (806-824MHz in up link and the 851-869MHz on down link) of U.S. FCC, the frequency (896-901MHz in up link and the 929-941MHz on down link) of U.S. FCC, the frequency (793-805MHz in up link and the 763-775MHz on down link) of U.S. FCC, the frequency of U.S. FCC (2495-2690MHz on up link and down link).
Down link electricity RF signal of communication 96 (1)-96 (R) is provided in this execution mode the multiple optical interfaces 98 (1)-98 (N) being arranged to optical interface module (OIM) form, to convert down link electricity RF signal of communication 96 (1)-96 (R) to downlink optical signals 100 (1)-100 (R).Symbol " 1-N " represents can arrange an arbitrary number described assembly 1-N.OIM98 can be configured to provide the one or more optical interface assemblies containing O/E and E/O transducer (OIC), hereafter will be described in more detail this.OIM98 supports the radio bands that can be provided by RIM92, example described hereinbefore before comprising.Therefore, in this embodiment, OIM98 can support the radio bands of (such as) 400MHz to 2700MHz, therefore the OIM98 provided for the dissimilar of narrower radio bands or model is not provided, just can tackles the possibility that RIM92 set in HEU94 supports different radio electric frequency band.In addition, such as, can optimize OIM98 for the sub-band in 400MHz to 2700MHz frequency range, described sub-band is, such as, and 400-700MHz, 700MHz to 1GHz, 1GHz to 1.6GHz and 1.6GHz to 2.7GHz.
The each self-contained E/O transducer of OIM98 (1)-98 (N), to convert down link electricity RF signal of communication 96 (1)-96 (R) to downlink optical signals 100 (1)-100 (R).Downlink optical signals 100 (1)-100 (R) is transferred to multiple RAU102 (1)-102 (P) via downlink optical fiber 103D.Symbol " 1-P " represents can arrange an arbitrary number described assembly 1-P.Downlink optical signals 100 (1)-100 (R) is converted back down link electricity RF signal of communication 96 (1)-96 (R) by the O/E transducer be arranged in RAU102 (1)-102 (P), and down link electricity RF signal of communication 96 (1)-96 (R) is supplied to the client terminal device in the range of receiving of antenna 106 (1)-106 (P) via the link 104 (1)-104 (P) be coupled with the antenna 106 (1)-106 (P) in RAU102 (1)-102 (P).
E/O transducer is also provided with in RAU102 (1)-102 (P), to convert uplink optical signal 108 (1)-108 (R) by by antenna 106 (1)-106 (P) to from the uplink electrical RF signal of communication that client terminal device receives, uplink optical signal 108 (1)-108 (R) will be transferred to OIM98 (1)-98 (N) via uplink optical fiber 103U.OIM98 (1)-98 (N) comprises O/E transducer, described O/E transducer converts uplink optical signal 108 (1)-108 (R) to uplink electrical RF signal of communication 110 (1)-110 (R), uplink electrical RF signal of communication 110 (1)-110 (R) is processed by RIM92 (1)-102 (M), and becomes uplink electrical RF signal of communication 112 (1)-112 (R).
May need for client terminal device provides digital data service and RF communication service.Such as, at building foundation facility 70(Fig. 3) in, digital data service and RF communication service may be needed to be supplied to the client terminal device being arranged in building foundation facility 70.Wired and wireless device can be arranged in building foundation facility 70, and these devices are configured to incoming digital data service.The example of digital data service is including (but not limited to) Ethernet, WLAN, WiMax, WiFi, Digital Subscriber Line (DSL) and LTE etc.Ethernet standard can be supported, including (but not limited to) 100 MBPSs (Mbs) (that is, Fast Ethernet) or gigabit (Gb) Ethernet or ten gigabits (10G) Ethernet.The example of Digital Data Set is including (but not limited to) wired and wireless server, WAP (wireless access point) (WAP), gateway, desktop computer, hub, interchanger, remote radio heads (RRH), Base Band Unit (BBU) and femtocell.Independently digital data service network can be provided, so that digital data service is supplied to Digital Data Set.
Based in the distributing antenna system 120 of optical fiber, the digital data service being derived from RF communication service is provided to RAU via separate downlink optical fiber and uplink optical fiber, and Fig. 5 is the schematic diagram of an illustrative embodiments of this process.The described distributing antenna system 120 based on optical fiber comprise in Fig. 1 to Fig. 3 based on some assemblies set in the distributing antenna system 10 of optical fiber.In Fig. 5, the component number of these common components illustrated is identical with the component number of these common components in Fig. 1 to Fig. 3.But, it should be noted that the distributing antenna system 120 based on optical fiber can also adopt other assemblies, comprise in Fig. 4 based on those assemblies in the distributing antenna system 90 of optical fiber.
As shown in Figure 5, HEU12 is provided with.HEU12 is from BTS88 receiving downlink electricity RF signal of communication 18D.As previously discussed, HEU12 converts down link electricity RF signal of communication 18D to down link light RF signal of communication 22D, and signal of communication 22D will distribute to RAU14.HEU12 is also configured to convert the uplink optical RF signal of communication 22U being received from RAU14 to uplink electrical RF signal of communication 18U, and signal of communication 18U will be provided to BTS88 and is provided to and is connected on the network 122 of BTS88.Distributing frame 123 can be provided to receive downlink optical fiber 16D and uplink optical fiber 16U, and downlink optical fiber 16D and uplink optical fiber 16U is configured to bearing downlink link light RF signal of communication 22D and uplink optical RF signal of communication 22U.Downlink optical fiber 16D and uplink optical fiber 16U can bundle and be placed in one or more riser cable 84, and is supplied to one or more ICU85, as previously discussed and as illustrated in figure 3.
In this embodiment, in order to provide digital data service in based on the distributing antenna system 120 of optical fiber, be provided with the digital data service controller (also referred to as " DDS controller ") 124 of the medium converter form in this example.DDS controller 124 only can comprise the medium converter for providing medium conversion facilities, or can comprise extra function to facilitate digital data service.DDS controller 124 is configured to provide digital data service via communication link, interface or other communication channels or circuit (can be wired or wireless or both combinations).DDS controller 124 can comprise shell, and described shell is configured to storage digital media converter (DMC) 126, DMC126 is connected to DDS interchanger 127 by interface, thus supports and provides digital data service.Such as, DDS interchanger 127 can be ethernet switch hub.Such as, DDS interchanger 127 can be configured to provide gigabit (Gb) Ethernet digital data service.DMC126 is configured to convert electric digital signal to light digital signal, and vice versa.DMC126 can be configured to be installed in DDS controller 124 according to the mode (that is, installation and operation configure without the need to user) of plug and play.Such as, DMC126 can comprise Ethernet input connector or adapter (such as, RJ-45) and optical fiber out connector or adapter (such as, LC, SC, ST, MTP).
Continue with reference to figure 5, DDS controller 124(in this execution mode is through DMC126) be configured to convert the down link electricity digital signal received from DDS interchanger 127 via digital line cable 129 (down link electricity digital data service signal) 128D to down link light digital signal (down link light digital data service signal) 130D, down link light digital signal 130D can be transferred to RAU14 via downlink optical fiber 135D.DDS controller 124(is through DMC126) be also configured to via uplink optical fiber 135U from RAU14 receiving uplink light digital signal 130U, and convert uplink optical digital signal 130U to uplink electrical digital signal 128U, uplink electrical digital signal 128U will be transferred to DDS interchanger 127.In this way, digital data service can be provided via as the optical fiber based on the part in the distributing antenna system 120 of optical fiber, thus the digital data service except RF communication service is provided.The client terminal device being positioned at RAU14 place can access these digital data service and/or RF communication service according to their configuration.Exemplary digital data services package is containing WLAN, Ethernet, WLAN, WiMax, WiFi, Digital Subscriber Line (DSL) and LTE etc.Ethernet standard can be supported, including (but not limited to) 100 MBPSs (Mbs) (that is, Fast Ethernet) or gigabit (Gb) Ethernet or ten gigabits (10G) Ethernet.
Continue with reference to figure 5, in this embodiment, downlink optical fiber 132D and uplink optical fiber 132U is arranged on and is connected in the fiber optic cables 134 of ICU85 by interface.ICU85 provides common point, and in described common point, the downlink optical fiber 132D of carrying digital optical signal and uplink optical fiber 132U can bundle with the downlink optical fiber 16D of carrying light RF signal of communication and uplink optical fiber 16U.Fiber optic cables 134(is herein also referred to as array cable 134) in one or more cable can contain downlink optical fiber 135D and uplink optical fiber 135U, RF communication service and digital data service route are provided to RAU14.Any combination of many services or polytype optical fiber can be arranged in array cable 134.Such as, array cable 134 can comprise monotype for RF communication service and/or digital data service and/or multi-mode optical fiber.
Can be arranged in the distributing antenna system 120 based on optical fiber, with the example of the ICU distributed downlink optical fiber 135D and the uplink optical fiber 135U for RF communication service and digital data service, being described in the title submitted on May 15th, 2009 is " PowerDistributionDevices, Systems, andMethodsForRadio-Over-Fiber (RoF) DistributedCommunication " U.S. patent application case the 12/466th, the title that No. 514 and on May 2nd, 2010 submit to is " PowerDistributioninOpticalFiber-BasedDistributedCommunic ationsSystemsProvidingDigitalDataandRadioFrequency (RF) CommunicationsServices, andRelatedComponentsandMethods " U.S. Provisional Application case the 61/330th, in No. 385, the mode that two application cases are quoted all is in full incorporated herein.
Continue with reference to figure 5, it can be access point (AP) or other devices supporting digital data service that some RAU14 can be connected to access unit (AU) 138, AU138.AU138 can also be directly connected to HEU12.Although picture in picture has shown that AU138, AU138 can be any other devices supporting digital data service.In the example of AU, AU138 provides the access to the digital data service that DDS interchanger 127 provides.This is because, downlink optical fiber 135D and uplink optical fiber 135U is supplied to AU138 via array cable 134 and RAU14, and the down link electricity digital signal 128D and uplink electrical digital signal 128U that optical fiber 135D and optical fiber 135U carries from being received from DDS interchanger 127 changes the down link light digital signal 130D and uplink optical digital signal 130U that come.Numerical data client terminal device can access AU138, thus accesses the digital data service provided by DDS interchanger 127.AU138 can also comprise antenna 140 separately, to provide the wireless access to the digital data service provided by DDS interchanger 127.
According to the more detailed description of hereafter will carry out, in RAU14 and/or AU138 providing RF communication service and digital data service to relate in Fig. 5 example, RF communication module and DDS module are set.These modules are power consumption modules, need electric power to operate.The electric power distributing to RAU can also be used for for DDS modules with power, and this is different from as DDS module and RF communication module provide separately independently power supply.Such as, based in optical fiber distributed type antenna system 120, the AU138 that the electric power distributing to RAU14 in Fig. 5 by ICU85 can also be used for being positioned at RAU14 place provides electric power.In this respect, ICU85 can be configured to via power line 142 for RAU14 and AU138 provides electric power, as shown in Figure 5.According to hereafter same more detailed description of will carry out, RAU14 and/or AU138 can also be configured to have power supply port, so that for the external client's end device (such as, IEEE802.3af Power over Ethernet (PoE) compatible apparatus) being connected to described power supply port provides electric power.But with reference to figure 5, as an example, the electric power being supplied to RAU14 and AU138 may be not enough to power to set all modules and all external device (ED)s of being connected to RAU14 and AU138.
In this respect, hereafter disclosed execution mode comprises the electrical management for RAU in distributing antenna system, and relevant apparatus, system, method and computer-readable media.The operation required electric power being configured to the RAU powered to multiple module and multiple device may exceed the obtainable electric power of RAU, and electrical management can carry out for this RAU.Such as, RAU can be configured to comprise power consumption RAU module, to provide the service relevant to distributing antenna system.Again such as, RAU can be configured to by the power supply port in RAU externally power consumer apparatus electric power is provided.According to the configuration of RAU, power consumption RAU module and/or the electric power required for outside power consumer apparatus may exceed the electric power that can obtain at RAU place.In this example, the electric power that can obtain at RAU place can distribute to power consumption module and device based on the priority of the service that need be provided by RAU.
Fig. 6 is the schematic diagram of the exemplary RAU14 being configured to have power consumption components.RAU14 is configured to receive electric power via the power line 150 being routed to RAU14 from local power supply or remote power supply, thus provides electric power for the power consumption components be associated with RAU14.As a limiting examples, power line 150 can 48 (48) be provided to lie prostrate according to the rated power between 80 (80) watts and 100 (100) watts and 60 (60) lie prostrate between voltage.In this example, RAU14 comprises the RF communication module 152 for providing RF communication service.RF communication module 152 needs electric power to operate in this embodiment, and receives electric power from power line 150.Electric power can be routed directly to RF communication module 152 from power line 150, or routes indirectly to RF communication module 152 from another module.Any assembly described before RF communication module 152 can comprise, with the RF communication service of providing package containing O/E and E/O conversion.
Continue with reference to figure 6, RAU14 can also comprise DDS module 154, to provide change of medium (such as, O/E and E/O changes), and the digital data service of the DDS interchanger 127 be received from Fig. 5 be routed to and be connected to outside power consumer apparatus (PD) 156 (1)-156 (Q), PD156 (1)-156 (Q) is configured to receiving digital data service.Electric power can be routed to DDS module 154 by RF communication module 152 from power line 150, and this is example electric power being routed to DDS module 154 from power line 150.Route digital data service is carried out by the communication port 158 (1)-158 (Q) be arranged in RAU14 with reference to figure 6, DDS module 154.As a limiting examples, communication port 158 (1)-158 (Q) can be RJ-45 connector.Communication port 158 (1)-158 (Q) can obtain electric power, this means to be provided to powered communication port one 58 (1)-158 (Q) from the part in the electric power of power line 150.In this way, when PD156 (1)-156 (Q) is connected to powered communication port one 58, the PD156 (1)-156 (Q) being configured to be received by powered communication port one 58 electric power can obtain electric power from the electric power being supplied to RAU14.In this way, just not needing with other independently power supply is PD156 (1)-156 (Q) power supply.Such as, DDS module 154 can be configured to electric power is routed to powered communication port one 58 (1)-158 (Q), as described in PoE standard.
Continue with reference to figure 6, one or more Remote Expansion unit (RXU) 160 (1)-160 (Z) also can be connected to RAU14.Except providing except extra RF communication service from RAU14 with remote mode, RXU160 (1)-160 (Z) can also be set to be provided extra RF communication service by RAU14.Such as, if need extra RF communication band and there is not available additional band in distributing antenna system, so can expand the RF communication band of existing RAU14, and without the need to by providing RXU160 (1)-160 (Z) to obtain extra communication band.RXU160 (1)-160 (Z) is connected to distributing antenna system by RAU14.RXU160 (1)-160 (Z) can comprise assembly same or similar with the assembly be arranged in RF communication module 152, with receiving downlink RF signal of communication 162D, and by RAU14, the up link RF signal of communication 162U being received from client terminal device is supplied to distributing antenna system.RXU160 (1)-160 (Z) is also power consumption module, and thus in this embodiment, the electric power from power line 150 is routed to RXU160 (1)-160 (Z) via power line 164 by RAU14.
The electric power be provided on the power line 150 in Fig. 6 may be not enough to provide electric power to the module 152,154,160 (1)-160 (Z) be arranged in RAU14 and outside PD156 (1)-156 (Q).Such as, the power of 80 (80) watts can be provided on the power line 150 in Fig. 6.But RF communication module 152 may consume the power of 30 (30) watts, RXU160 (1)-160 (Z) may consume the power of 20 (20) watts, and DDS module 154 may consume the power of five (5) watts.Like this, 55 (55) watts are total up to.In this example, being used in the power shared between powered communication port one 58 (1)-158 (Q) is 25 (25) watts.But PD156 (1)-156 (Q) can be configured and need to exceed the power of 25 (25) watts.Such as, if configure PD156 (1)-156 (Q) according to PoE standard, be so arranged in RAU14 for providing the power-supply device of electric power (PSE) may need to provide power up to 15.4 watts to each powered communication port one 58 (1)-158 (Q) to powered communication port one 58 (1)-158 (Q).In this example, if be provided with more than one powered communication port one 58 (1)-158 (Q), so just there is no enough electric power to power to each in the powered communication port one 58 (1)-158 (Q) of needs 30 watts (that is, PoEClass4 device).
Therefore, module 152,154,160 (1)-160 (Z) in order to ensure the consumption maximum power that may have in RAU14 carries out proper operation, less electric power can be provided to powered communication port one 58 (1)-158 (Q), or an only powered communication port one 58 (1)-158 (Q) can be enabled with electric power.But, if the one in other modules 152,154,160 (1)-160 (Z) is non-existent, so obtainable electric power is just enough to be supplied to each in set powered communication port one 58 (1)-158 (Q).In addition, if the PD156 being connected to powered communication port one 58 is the lower grade device not needing 30 watts of power, so obtainable electric power is just enough to PD156 (1)-156 (Q) power supply to being connected to each in powered communication port one 58 (1)-158 (Q).
In this respect, Fig. 7 is the exemplary priority scheme of power management scheme, and described power management scheme provides enough electric power for the power consumption module for being powered by RAU14 and PD.In this example, the priority of RF communication service has been assigned to higher than the priority of digital data service with power supply port.Therefore, in this example, the electric power that can obtain from power line 150 will be provided to RF communication module 152.If after making power budget for RF communication module 152, can obtain more electric power from power line 150, so dump power is provided to RXU160 (1)-160 (Z) to provide expansion RF communication service.If after making power budget for RF communication module 152 and RXU160 (1)-160 (Z), can obtain more electric power from power line 150, so dump power is provided to DDS module 154 to provide digital data service.If after making power budget for RF communication module 152, RXU160 (1)-160 (Z) and DDS module 154, can obtain more electric power from power line 150, so dump power is provided to powered communication port one 58 (1)-158 (Q) to provide electric power to PD156 (1)-156 (Q).It should be noted that the priority of planning in Fig. 7 is exemplary, and any other required precedence scheme can be implemented in power management scheme.
Continue with reference to figure 7, the power budget done is, obtainable electric power is enough to PD158 (1) power supply to being connected to the first powered communication port one 58 (1).If after making power budget for RF communication module 152, RXU160 (1)-160 (Z), DDS module 154 and the PD158 (1) that is connected to the first powered communication port one 58 (1), more electric power can be obtained from power line 150, so electric power is provided to other powered communication port ones 58 (2)-158 (Q), until obtainable electric power is not enough to PD156 (2)-156 (Q) power supply to being connected to extra powered communication port one 58 (2)-158 (Q).If dump power budgetary shortfall is to power to the PD156 being connected to any powered communication port one 58, so these powered communication port ones 58 can be stopped using.In addition, if for specific RAU14, any module is had not exist or be removed in module 152,154,160 (1)-160 (Z), so the obtained power budget of powered communication port one 58 (1)-158 (Q) can increase, thus the powered communication port one 58 (1)-158 (Q) of stopping using before enabling.
Fig. 8 is to carry out the schematic diagram of an illustrative embodiments of the assembly of remote power management in the RAU14 that can be arranged on Fig. 6, and described assembly carries out remote power management to the electric power being supplied to power consumption module 152,154,160 (1)-160 (Z) and being connected to outside PD156 (1)-156 (Q).In Fig. 8, composition graphs 9 describes to the flow chart in Figure 11 by the discussion of the remote power management of RAU14.Fig. 9 be a diagram that the flow chart of the exemplary remote electrical management process that HEC44 provides in Fig. 2, and described remote power management process is for performing the remote power management at RAU14 place.Figure 10 be a diagram that the flow chart of the exemplary power management process that RAU14 provides, and described electrical management process is used at initial phase and the electric power managing RAU14 place when the configuration of RAU14 is changed.Figure 11 be a diagram that the flow chart of the exemplary power management process that RAU14 provides, described electrical management process is used for the electric power that management is supplied to PD156 (1)-156 (Q), and PD156 (1)-156 (Q) is connected to the powered communication port one 58 (1)-158 (Q) be arranged in RAU14.
Power-supply device (PSE) 170 is comprised with reference to figure 8, RAU14.Power line 171 receives electric power by RF communication module 152 from power line 150, and PSE170 is configured to electric power to guide to the PD156 (1)-156 (Q) being connected to powered communication port one 58 (1)-158 (Q) from power line 171.To be arranged in DDS module 154 and the obtained power budget that the controller 176 being coupled to memory 178 is configured to according to being received from HEC44 provides power management capabilities, hereinafter with reference to Fig. 9 to Figure 11, this to be described in more detail.PSE170 can provide the obtained power budget from power line 150, to power to the PD156 (1)-156 (Q) being connected to powered communication port one 58 (1)-158 (Q), power budget can be obtained described in receiving, PSE170 can manage the electric power guiding to PD156 (1)-156 (Q) (being connected to powered communication port one 58 (1)-158 (Q)), and without the need to stoping other modules 152,154,160 (1)-160 (Z) be present in RAU14 to receive the electric power being enough to carry out operating.
As shown in Figure 9, in order to provide the electrical management at RAU14 place, have employed the HEC44 in HEU12.Each RAU14, HEC44 are received to the configuration (square frame 180 in Fig. 9) of the power consumption module 152,154,160 (1)-160 (Z) be present in RAU14.HEC44 communicates with RAU14 by using the digital communication transmitted via communication link, and described communication link is identical with the communication link for carrying RF signal of communication.The U.S. Provisional Application case the 61/230th that the title submitted on July 31st, 2009 is " OpticalFiber-BasedDistributedAntennaSystems; Components; andRelatedMethodsforMonitoringtheStatusThereof " is described in about providing the more information of digital communication and control system in distributing antenna system, in No. 472, this application case is incorporated herein by reference in full.HEC44 decides the electric power (square frame 182 in Fig. 9) needed for module 152,154,160 (1)-160 (Z) be present in RAU14 by inquiry memory cell 46.Such as, memory cell 46 can be programmed by the power consumption speed relevant to dissimilar module 152,154,160 (1)-160 (Z), and HEC44 can search described power consumption speed in memory cell 46.
According to the discussion carried out hereinafter with reference to Figure 10, RAU14 can provide specific hardware and/or software element, and/or being present in multiple versions of those elements of the module 152,154,160 (1)-160 (Z) in RAU14, HEC44 can use these elements to decide the electrical power demand of module 152,154,160 (1)-160 (Z).Subsequently, by the electric power that the abundant power supply station of module 152,154,160 (1)-160 (Z) deducted by the total electricity being supplied to RAU14 as existing in RAU14 needs, HEC44 decides the obtained power budget of RAU14 accordingly, thus provides electric power (square frame 184 in Fig. 9) to any PD156 (1)-156 (Q) being connected to powered communication port one 58 (1)-158 (Q).The obtainable total electricity of RAU14 can be programmed in memory cell 46, comprises and is programmed by the graphic user interface (GUI) of HEU12 institute management and control by user or programmed by other configurations.For each RAU14 being configured for use in HEU12, described process can repeat.By performing the process in Fig. 9, RAU14 receives and can obtain power budget, and the described power budget that obtains can provide electric power through point PD156 (1)-156 (Q) be equipped with to being connected to powered communication port one 58 (1)-158 (Q) in RAU14.
RAU14 also performs the process for providing electrical management.Described process can be performed by the controller 176 in the DDS module 154 shown in Fig. 8.Figure 10 be a diagram that the flow chart of the exemplary power management process that RAU14 provides, and described electrical management process is used at initial phase and the electric power managing RAU14 place when the configuration of RAU14 is changed.RAU14 checks the configuration of the module 152,154,160 (1)-160 (Z) be present in RAU14, to determine whether the configuration of RAU14 changes (square frame 190).Such as, after upper once decision configures and configuration is supplied to HEC44, module 152,154,160 (1)-160 (Z) may be added or removes from RAU.If the configuration of RAU14 changes (square frame 192), so RAU14 obtains the hardware and software version (square frame 194) of module type and module 152,154,160 (1)-160 (Z).The hardware and software version of module type and module 152,154,160 (1)-160 (Z) is sent to HEC44(square frame 196 by RAU14 subsequently).In square frame 180 in fig .9, this information is received by HEC44, as before hereinbefore as described in.
Continue with reference to Figure 10, according to the process in Fig. 9, the obtained power budget for RAU14 (square frame 198) that HEC44 provides new waited for by the controller 176 in RAU14.When obtaining power budget described in receiving (square frame 200), controller 174 determines whether DDS module 154 is arranged on (square frame 202) in RAU14.If not, so controller 176 determines whether installed RXU module 160 (1)-160 (Z) (square frame 204).If not, then described process is repeated.If installed RXU module 160 (1)-160 (Z) (square frame 204), so controller 176 has determined whether RXU module 160 (1)-160 (Z) opens (square frame 206).If so, then described process is repeated.If not, so controller 176 indicates RF communication module 152 to open RXU module 160 (1)-160 (Z) (square frame 208), and repeats described process.
Continue with reference to Figure 10, if controller 176 determines to have installed DDS module 154(square frame 202), so just mean that digital data service is provided by RAU14.The powered communication port one 58 existed in this example allows PD156 (1)-156 (Q) to be connected to powered communication port one 58 (1)-158 (Q), thus the digital data service making PD156 (1)-156 (Q) that DDS module 154 can be received to support.In this respect, controller 176 guides PSE170 the obtained power budget being received from HEC44 to be sent to powered communication port one 58 (1)-158 (Q) (square frame 210) in RAU14.According to power budget can be obtained and be connected to the electrical power demand of PD156 (1)-156 (Q) of powered communication port one 58 (1)-158 (Q), can enable or stop using and be connected to the PD156 (1)-156 (Q) of powered communication port one 58 (1)-158 (Q).Controller 176 etc. is connected to the state (square frame 212) of the PD156 (1)-156 (Q) of powered communication port one 58.When the state of the PD156 (1)-156 (Q) being connected to powered communication port one 58 (1)-158 (Q) is received (square frame 214), described state is sent to HEC44(square frame 216 by controller 176).Subsequently, if there is RXU module 160 (1)-160 (Z) and RXU module 160 (1)-160 (Z) is not also opened, so controller 176 is RXU module 160 (1)-160 (Z) power supply (square frame 204,206,208).
Figure 11 be a diagram that the flow chart of the exemplary power management process that RAU14 provides, described electrical management process is used for changing (namely to the state at powered communication port one 58 (1)-158 (Q), connect or disconnect) time manages the electric power being supplied to PD156 (1)-156 (Q), and powered communication port one 58 (1)-158 (Q) is arranged in RAU14.If the state of arbitrary powered communication port one 58 (1)-158 (Q) improves electrical power demand, such as, owing to there is new connection or being connected with the PD156 of the more electric power of needs, so may need other powered communication port ones 58 (1)-158 (Q) inactive, can obtain in the scope of power budget to remain on.If the state of arbitrary powered communication port one 58 (1)-158 (Q) reduces electrical power demand, so can enable other powered communication port ones 58 (1)-158 (Q), this is can obtain in the scope of power budget to remain on equally.
With reference to Figure 11, controller 176 determines whether the configuration of RAU14 changes (square frame 220).If changed (square frame 222), so controller 176 determines whether described change occurs (square frame 224) because of the state change of powered communication port one in RAU14 58 (1)-158 (Q).Although be carry out electrical management to two (2) powered communication port ones 58 (1), 158 (2) in this example, the powered communication port obtaining managing can have any number.If powered communication port one 58 (1)-158 (Q) does not change, so just mean for PD156 (1)-156 (Q) provides the obtained power budget of electric power to change, because at least one module 152,154,160 (1)-160 (Z) has been removed or has been added in RAU14.In this example, controller 176 determines whether PD156 (1) is connected to the first powered communication port one 58 (1) (square frame 226) of not powering.If so, so controller 176 determines whether can obtain power budget is enough to provide electric power (square frame 228) to the PD156 (1) being connected to the first powered communication port one 58 (1).If so, so controller 176 guides PSE170 to provide electric power (square frame 230) to the first powered communication port one 58 (1).If not, so controller 176 checks the state (square frame 232) of the second powered communication port one 58 (2).
If controller 176 determines that the first powered communication port one 58 (1) does not obtain powering (square frame 226), so controller 176 determines whether PD156 (2) is connected to the second powered communication port one 58 (2) (square frame 232) of not powering.If so, so controller 176 determines whether can obtain power budget is enough to provide electric power (square frame 234) to the PD156 (2) being connected to the second powered communication port one 58 (2).If so, so controller 176 guides PSE170 to provide electric power (square frame 236) to the second powered communication port one 58 (2).If not, so controller 176 does not change the electrical arrangement of the second powered communication port one 58 (2).Therefore, controller 176 carrys out managing power in the following manner: can obtain power budget if existed, so enable the first powered communication port one 58 (1), and subsequently, if power budget can be obtained can be obtained after providing electric power to the first powered communication port one 58 (1), so enable the second powered communication port one 58 (2).When RAU14 obtained power budget change time, based on can obtain power budget reappraise enabling of powered communication port one 58 (1), 158 (2) or stop using.
If the state of powered communication port one 58 (1), 158 (2) changes (square frame 224), so the current power setting of powered communication port one 58 (1), 158 (2) is also reappraised.In this respect, if the first powered communication port one 58 (1) is connected (square frame 238), so controller 176 obtains the grade (square frame 240) of the PD156 (1) being connected to powered communication port one 58 (1) from PSE170.Controller 176 determines whether can obtain power budget is enough to the PD156 being in self class rating (1) power supply (square frame 242).If so, so controller 176 guides PSE170 to enable powered communication port one 58 (1), to provide electric power (square frame 244) to the PD156 (1) being connected to powered communication port one 58 (1).Such as, if can obtain power budget is 16 watts, so to being connected to powered communication port one 58 (1) and rated power is PoEClass3PD156 (1) power supply of 15.4 watts, thus powered communication port one 58 (1) can be enabled.But if rated power is 30 watts or less PoEClass4PD156 (1) be connected to powered communication port one 58 (1), so powered communication port one 58 (1) is deactivated, because can obtain power budget to be less than 30 watts.
The RAU14 that controller 176 comes in more new memory 178 based on the grade of the PD156 (1) being connected to powered communication port one 58 (1) can obtain power budget (square frame 246), thus avoids when not remaining enough power budget electric power being guided to the second powered communication port one 58 (2).If can obtain power budget be not enough to be connected to powered communication port one 58 (1) PD156 (1) power supply (square frame 242), so controller 176 is stopped using powered communication port one 58 (1), thus avoids PSE170 electric power to be supplied to powered communication port one 58 (1) (square frame 248).
If PD156 (1) is not connected to the first powered communication port one 58 (1) (square frame 238), so controller 176 determines whether the first powered communication port one 58 (1) is disconnected connection (square frame 249).If not, so controller 176 determines whether PD156 (2) is connected to the second powered communication port one 58 (2) (square frame 250).If so, so controller 176 obtains the grade (square frame 252) of the PD156 (2) being connected to powered communication port one 58 (2) from PSE170.Controller 176 determines whether can obtain power budget is enough to the PD156 being in self class rating (2) power supply (square frame 254).If so, so controller 176 guides PSE170 to enable powered communication port one 58 (2), to provide electric power (square frame 256) to the PD156 (2) being connected to powered communication port one 58 (2).The RAU14 that controller 176 comes in more new memory 178 based on the grade of the PD156 (2) being connected to powered communication port one 58 (2) can obtain power budget (square frame 246), thus avoids when not remaining enough power budget electric power being guided to another powered communication port one 58 (1).If can obtain power budget be not enough to be connected to powered communication port one 58 (2) PD156 (2) power supply (square frame 254), so controller 176 is stopped using powered communication port one 58 (2), thus avoids PSE170 electric power to be supplied to powered communication port one 58 (2) (square frame 258).
Figure 12 is the more detailed diagram of an execution mode of DDS module 154 in Fig. 8, DDS module 154 can be arranged in RAU14, to provide digital data service to the PD156 (1)-156 (Q) being connected to powered communication port one 58 (1)-158 (Q), and provide electrical management for powered communication port one 58 (1)-158 (Q), as described above.As shown in Figure 12, DDS module 174 comprises transmitting optics sub-unit (TOSA) 260 and receives optics sub-unit (ROSA) 262, the down link light digital signal 130D from downlink optical fiber 135D to be converted to down link electricity digital signal, and convert uplink electrical digital signal to uplink optical digital signal 130U.DDS interchanger 264 is for being switched to powered communication port one 58 (1)-158 (Q) by digital data service.Controller 176 is used as PoEPSE controller to manage the electric power being supplied to powered communication port one 58 (1)-158 (Q).Power interface 266 is for receiving electric power from the power line 171 from RF communication module 152.Interchanger 268 and light-emitting diode (LED) 270 are respectively used to the state realizing configuration setting and provide DDS module 174.
Figure 13 is that the schematic diagram of exemplary electronic device 280 represents, its exemplary form is exemplary computer system 282, and computer system 282 for performing the instruction from exemplary computer readable media, thus performs power management capabilities.Electronic installation 280 can be DDS module 154, and can be arranged on any other module in RAU14 or device.Electronic installation 280 can be arranged to independent of being other modules 152,154,160 (1)-160 (Z) of RAU14 configuration.In this respect, electronic installation 280 can comprise computer system 282, in computer system 282, can perform the instruction set for making electronic installation 280 perform any one or more discussed methods herein.Electronic installation 280 can be connected to the other machines (such as, networking with described other machines) in LAN, Intranet, extranet or internet.Electronic installation 280 can operate under master-slave network environment, or operates as peer machines (peermachine) under equity (or distributed) network environment.Although illustrate only single assembly, term " device " also should comprise separately or jointly perform (or multiple) instruction set to perform the arbitrary collection of the device of any one or more discussed methods herein.Electronic installation 280 can be server, personal computer, desktop computer, portable computer, PDA(Personal Digital Assistant), calculator (computingpad), mobile device or any other device, and can represent (such as) server or subscriber computer.
Exemplary computer system 282 comprises processing unit or processor 284, main storage 286(such as, read-only memory (ROM), flash memory, dynamic random access memory (DRAM) (as synchronous DRAM(SDRAM)) etc.) and static memory 288(such as, flash memory, static RAM (SRAM) etc.), everyly can to intercom via bus 290 phase above.Or processing unit 284 can be directly connected to main storage 286 and/or static memory 288, or can connect via some other connecting elementss.Processing unit 284 can be controller 176, and main storage 286 or static memory 288 can be memories 178.
Processing unit 284 represents one or more general processing unit, such as, and microprocessor, CPU etc.More specifically, processing unit 284 can be that sophisticated vocabulary calculates (CISC) microprocessor, Jing Ke Cao Neng (RISC) microprocessor, very long instruction word (VLIW) microprocessor, performs the processor of other instruction set or perform the processor of combination of multiple instruction set.Processing unit 284 is configured to perform the processing logic in instruction 292, thus performs discussed operation and step herein.
Computer system 282 can comprise Network Interface Unit 294 further.Computer system 282 can also comprise or can not comprise for the input 296 receiving input and select, and described input and selection will be transferred to processing unit 284 when system performs instruction.Computer system 282 can also comprise or can not comprise output 298, output 298 including (but not limited to) display, video display unit (such as, liquid crystal display (LCD) or cathode ray tube (CRT)), alphanumeric input device (such as, keyboard) and/or cursor control device (such as, mouse).
Computer system 282 can comprise or can not comprise data storage device, described data storage device comprises the instruction 300 be stored in computer-readable media 302, and computer-readable media 302 can implement described any one or more RAU14 electric power management method or functions herein.During computer system 282 performs instruction 300, instruction 300 can also reside in main storage 286 and/or processing unit 284 completely or at least in part, and main storage 286 and processing unit 284 form computer-readable media equally.Instruction 300 can be launched further via Network Interface Unit 294 or receive on network 304.
Although the computer-readable media 302 shown in an illustrative embodiments is single mediums, but term " computer-readable media " should comprise the single medium that stores one or more instruction set or multiple media (such as, centralized or distributed data base and/or the cache memory be associated and server).Term " computer-readable media " also should comprise and can store the instruction set performed by processor, encodes or carry and make processor perform any media of any one or more methods of disclosed execution mode herein.Correspondingly, term " computer-readable media " should including (but not limited to) solid-state memory, optical media and magnetic medium, and carrier signal.
The digital data service of any type can be provided to DDS module disclosed herein.The powered communication port be arranged in RAU can through arranging to meet any electric power standard.In the example of PoE, IEEE802.3at specifies that described assembly can use and support Link Layer Discovery Protocol (LLDP) herein, and described assembly comprises controller in RAU and electrical management assembly.LLDP allows to carry out exchanges data with PD, thus determines the rated power of PD.In addition, more precise informations of relevant electrical power demand can only use the LLDP(of media endpoints device according to TIA-1057, such as, LLDP-MED) exchange.LLDP-MED allows PD to ask the electric power of (step-length is 0.1 watt) between 0 watt to 102.3 watts.LLDP and LLDP-MED is Layer2 protocol (layer2protocol), and this agreement needs component receive those Ethernet data bags from PD and those Ethernet data bags are transmitted into PD.Described transmitting and receiving can be performed by the controller in the RAU of being arranged on disclosed herein, and described RAU has the Ethernet MAC controller be connected with the ethernet switch hub of medium converter inside.Or the rated power of PD can manually be set in RAU by the operator conducted interviews to the RAU in distributing antenna system or be programmed in RAU.
Execution mode disclosed herein comprises multiple step.The step of disclosed execution mode can be performed by nextport hardware component NextPort herein, or can implement in machine-executable instruction, and described machine-executable instruction may be used for making the universal or special processor enrolling described instruction perform described step.Or described step can be performed by the combination of hardware and software.
Execution mode disclosed herein can as computer program or software, the machine-readable medium (or computer-readable media) that storage inside has instruction can be comprised, may be used for for computer system (or other electronic installations) programming, thus perform the process according to disclosed execution mode herein.Machine-readable medium comprises for storing or any mechanism of transmission information with machine (such as, computer) readable form.Such as, machine-readable medium comprises machine-readable storage media (such as, read-only memory (" ROM "), random access memory (" RAM "), magnetic disc storage media, optic storage medium, flash memory device etc.), machine readable transmission medium (electricity, light, sound or other forms of transmitting signal (such as, carrier wave, infrared signal, digital signal etc.)) etc.
Unless expressly stated otherwise, such as, can understand from foregoing teachings easily, otherwise should be appreciated that, in all descriptions, use " process ", " calculating ", " decision ", the discussion of terms such as " displays " refers to action and the process of computer system or similar computing electronics, described system and device utilize and are expressed as data that in computer system RS, physics (electronics) is measured and described data are transformed into other data, be expressed as computer system memory or register or other this type of informations like other data class described to store, transmission or display unit in physical quantity.
Algorithm proposed herein is not natively relevant to any certain computer or other equipment with display mode.The many general system had according to the program of teaching herein can be used, or can prove, structure more targetedly equipment to perform the desired method step be very easily.Structure needed for this type systematic multiple occurs in the description above.In addition, described herein execution mode is not describe with reference to any certain programmed language.Should be appreciated that, multiple programming language can be used implement the teaching of described execution mode herein.
Those skilled in the art will understand further, electronic hardware can be embodied as in conjunction with disclosed execution mode describes herein various illustrative components, blocks, module, circuit and algorithm, store in memory or the instruction performed in another computer-readable media and by processor or other processing unit, or both combinations.Assembly in distributing antenna system described herein can be used in (such as) any circuit, nextport hardware component NextPort, integrated circuit (IC) or IC chip.Memory disclosed herein can be the memory of any type and size, and can be configured to the information needed storing any type.In order to this interchangeability is clearly described, substantially functionally describe various Illustrative components, square frame, module, circuit and step above.The execution mode of this type of function depends on application-specific, design alternative and/or is applied to the design constraint of whole system.Those skilled in the art can implement described function by different way for each application-specific, but this type of implementation decision should not be interpreted as causing departing from scope of the present invention.
Can implement with any combination that the processor performing described function herein, digital signal processor (DSP), application-specific integrated circuit (ASIC) (ASIC), field programmable gate array (FPGA) or other programmable logic devices, discrete gate or transistor-transistor logic circuit, discrete hardware components or more are every or perform with through design in conjunction with described execution mode describes herein various illustrative components, blocks, module and circuit.Controller can be processor.Processor can be microprocessor, but as an alternative, processor can be any conventional processors, controller, microcontroller or state machine.Processor can also be embodied as the combination of calculation element, such as, the combination of DSP and microprocessor, multi-microprocessor, the one or more microprocessor be combined with DSP core or any other this type of configure.
Execution mode disclosed herein within hardware and can store in instruction within hardware and implement, and can reside in (such as) random-access memory (ram), flash memory, read-only memory (ROM), electrically programmable ROM(EPROM), electrically erasable ROM(EEPROM), in the computer-readable media of any other form known in register, hard disk, moveable magnetic disc, CD-ROM or affiliated field.Exemplary storage medium is coupled to processor, can write described medium to make processor from described read information and by information.As an alternative, medium can integrate with processor.Processor and medium can reside in ASIC.ASIC can be in the remote station resident.As an alternative, processor and medium can reside in distant station, base station or server as discrete component.
It shall yet further be noted that the operating procedure described in any illustrative embodiments is for providing example and discussion herein.The operation described, except can performing according to illustrated order, can perform according to many different order.In addition, in fact the multiple operations described in single operation step can perform in some different steps.In addition, the one or more operating procedures discussed in illustrative embodiments can also be combined.Should be understood that the operating procedure illustrated in flow chart can obtain many difference amendments, this is that those skilled in the art easily understands.Those skilled in the art should also be understood that and the arbitrary technology in multiple different technologies and technique and technique can be used to represent information and signal.Such as, the data quoted in all descriptions hereinbefore, instruction, order, information, signal, bit, symbol and chip can represent by the combination in any that voltage, electric current, electromagnetic wave, magnetic field or magnetic particle, light field or light particle or more are every.
In addition; term used herein " fiber optic cables " and/or " optical fiber " should comprise all types of single mode or multimode lightguide pipe; comprise one or more optical fiber; these optical fiber can be band coating, painted, be buffered, prick have band; and/or in cable (such as, one or more pipe, one or more reinforcement, sheath etc.), there is its hetero-organization or operator guards.Optical fiber disclosed herein can be single mode or multimode fiber.Similarly, the appropriate optical fibers of other types comprises the optical fiber to bend-insensitive, or for any other alternative articles for use of the media of transmitting optical signal.To the example of bend-insensitive or resistant to bending optical fiber for buying from Corning Incorporated (CorningIncorporated) multimode fiber.Such as, disclose the appropriate optical fibers of this type in U.S. Patent Application Publication case No. 2008/0166094 and No. 2009/0169163, the disclosure of described publication is incorporated herein by reference in full.
Those skilled in the art, after the advantage understanding the teaching presented in aforementioned explanation and associated drawings, can find out many amendments and other execution modes that institute herein sets forth execution mode.

Claims (34)

1. an electrical management device, carry out telemanagement for the electric power consumed remote antenna unit (RAU) place in distributing antenna system, described electrical management device comprises:
Remote controllers, described remote controllers are coupled at least one remote antenna unit (RAU) be arranged in described distributing antenna system by correspondence, at least one outside power consumer apparatus that described RAU is configured to being connected at least one power supply port provides electric power, and without the need to stoping at least one power consumption RAU module be present in described RAU to receive the electric power being enough to carry out operating;
Wherein said remote controllers are configured to:
The obtained power budget determining at least one port of powering described is communicated with at least one RAU described; And
At least one RAU described is transferred to by power budget can be obtained described at least one power supply port described at least one RAU described,
Wherein said remote controllers are co-located in head-end unit (HEU), and described HEU is configured to downlink radio frequency (RF) signal of communication be distributed at least one RAU described.
2. electrical management device according to claim 1, wherein said remote controllers be configured to from described at least one RAU receive be present at least one RAU described described in the type of at least one power consumption RAU module.
3. electrical management device according to claim 2, wherein said remote controllers are configured to decide can obtain power budget described at least one power supply port described based on the electric power needed at least one power consumption RAU module described in being present at least one RAU described.
4. electrical management device according to claim 3, wherein said remote controllers are configured to determine that at least one power supply the described of port described obtains power budget, deciding means is, deducts the described electric power be present in described at least one RAU described needed at least one power consumption RAU module from the obtainable total electricity of at least one RAU described.
5. electrical management device according to claim 3, wherein said remote controllers are configured to search in the memory being coupled to described remote controllers the described electric power be present in described at least one RAU described needed at least one power consumption RAU module further.
6. electrical management device according to claim 3, wherein said remote controllers are configured to: at least one power consumption RAU module described in being present at least one RAU described, based on the type of at least one power consumption RAU module described in existing, determine to be present in the described electric power needed for described at least one power consumption RAU module at least one RAU described.
7. electrical management device according to claim 2, wherein said remote controllers are configured to the power state receiving at least one power supply port described from least one RAU described further.
8. the electric power for consuming remote antenna unit (RAU) place in distributing antenna system carries out a method for telemanagement, comprises the following steps:
The obtained power budget determining at least one port of powering is communicated with at least one RAU, at least one outside power consumer apparatus that at least one RAU described is configured to being connected at least one power supply port described provides electric power, and without the need to stoping at least one power consumption RAU module be present at least one RAU described to receive the electric power being enough to carry out operating; And
At least one RAU described is transferred to by power budget can be obtained described at least one power supply port described at least one RAU described; And
The power state of at least one power supply port described is received from least one RAU described.
9. method according to claim 8, described method is further comprising the steps: from described at least one RAU receive be present at least one RAU described described in the type of at least one power consumption RAU module.
10. method according to claim 9, said method comprising the steps of: can obtain power budget described at least one power supply port described in deciding at least one RAU described based on the electric power needed at least one power consumption RAU module described in being present at least one RAU described.
11. methods according to claim 10, said method comprising the steps of: determine that at least one power supply the described of port described obtains power budget, deciding means is, deducts the described electric power be present in described at least one RAU described needed at least one power consumption RAU module from the obtainable total electricity of at least one RAU described.
12. methods according to claim 10 or 11, described method is further comprising the steps: in the memory being coupled to remote controllers, search the described electric power be present in described at least one RAU described needed at least one power consumption RAU module.
13. methods according to claim 10 or 11, described method is further comprising the steps: at least one power consumption RAU module described in being present at least one RAU described, based on the type of at least one power consumption RAU module described in existing, determine to be present in the described electric power needed for described at least one power consumption RAU module at least one RAU described.
14. methods according to claim 10 or 11, described method is further comprising the steps: based on the version of described at least one power consumption RAU module, determines to be present in the described electric power needed for described at least one power consumption RAU module at least one RAU described.
15. methods according to claim 14, wherein said version is made up of particular demographic, and described group is made up of hardware version and software version.
16. 1 kinds of remote antenna units for distributing antenna system (RAU), comprising:
At least one power consumption RAU module;
At least one port of powering, at least one outside power consumer apparatus that described power supply port is configured to being connected at least one power supply port described provides electric power; And
RAU controller, described RAU controller is configured to:
The obtained power budget of at least one power supply port described is received from the remote controllers described distributing antenna system; And
Obtain power budget to be enough to power to being connected at least one outside power consumer apparatus described at least one power supply port described if described, so at least one power supply port described provides electric power, and without the need to stoping described at least one power consumption RAU module to receive the electric power being enough to carry out operating
Wherein said at least one power consumption RAU module is made up of at least one photoelectricity (O/E) transducer, and described O/E transducer is configured to convert down link light RF signal to downlink electrical RF signal.
17. RAU according to claim 16, wherein said at least one power consumption RAU module is made up of at least one item in following item: the RF communication module being configured to provide radio frequency (RF) communication service; And be configured to the DDS module that digital data service (DDS) is provided.
18. RAU according to claim 17, wherein said RAU controller is described DDS module.
19. according to aforementioned RAU according to claim 16, wherein said at least one power consumption RAU module is made up of at least one electric light (E/O) transducer, and described E/O transducer is configured to convert uplink electrical RF signals to uplink optical RF signals.
20. according to aforementioned RAU according to claim 16, and wherein said at least one power consumption RAU module comprises at least one Remote Expansion unit (RXU) module further, and described RXU module is configured to provide RF communication service.
21. RAU according to claim 20, at least one RXU module wherein said is configured to receiving downlink RF signal of communication.
22. RAU according to claim 20, at least one RXU module wherein said is configured to receiving uplink RF signal of communication.
23. according to aforementioned RAU according to claim 16, and at least one power supply port wherein said is made up of at least one Power over Ethernet (PoE) port.
24. according to aforementioned RAU according to claim 16, wherein said RAU controller is configured to further: be not enough to when being connected to that described at least one power supply port described, at least one outside power consumer apparatus is powered in the described power budget that obtains, at least one power supply port described of stopping using.
25. according to aforementioned RAU according to claim 16, and at least one power supply port wherein said comprises multiple power supply port,
Wherein said RAU controller is configured to further: when described obtain power budget be only enough to power at least one outside power consumer apparatus described at least one second port be connected in described multiple power supply port, at least one first port of stopping using in described multiple power supply port.
26. according to aforementioned RAU according to claim 16, and wherein said RAU controller is configured to determine whether the state of at least one power supply port described changes further.
27. RAU according to claim 26, wherein said RAU controller is configured to the device grade determining at least one the outside power consumer apparatus described being connected at least one power supply port described further.
28. RAU according to claim 27, wherein said RAU controller is configured to: be enough to when having that described in described device grade, at least one outside power consumer apparatus is powered in the described power budget that obtains, at least one power supply port described provides electric power.
29. RAU according to claim 27, wherein said RAU controller is configured to further: be not enough to when having that described in described device grade, at least one outside power consumer apparatus is powered in the described power budget that obtains, at least one power supply port described of stopping using.
30. 1 kinds of methods managed for the electric power consumed remote antenna unit (RAU) place in distributing antenna system, comprise the following steps:
Receive the obtained power budget of multiple power supply port, described power supply port is configured to, based on the electric power needed at least one power consumption RAU module, provide electric power at least one the outside power consumer apparatus being connected to described multiple power supply port;
Obtain power budget to be enough to power to being connected at least one outside power consumer apparatus described in described multiple power supply port if described, so for described multiple power supply port provides electric power, and without the need to stoping described at least one power consumption RAU module to receive the electric power being enough to carry out operating;
Obtain power budget to be not enough to power to being connected at least one outside power consumer apparatus described in described multiple power supply port if described, described multiple power supply port of so stopping using; And
Described method is further comprising the steps: obtain power budget is only enough to power at least one outside power consumer apparatus described at least one second port be connected in described multiple power supply port if described, at least one first port of so stopping using in described multiple power supply port.
31. methods according to claim 30, described method is further comprising the steps: determine whether the state of described multiple power supply port changes.
32. methods according to claim 31, described method is further comprising the steps: determine the device grade being connected at least one outside power consumer apparatus described of described multiple power supply port.
33. methods according to claim 32, described method is further comprising the steps: obtain power budget is enough to power to having at least one outside power consumer apparatus described in described device grade, so for described multiple power supply port provides electric power if described.
34. methods according to claim 32, described method is further comprising the steps: obtain power budget if described and be not enough to power to having at least one outside power consumer apparatus described in described device grade, so stops as described multiple feeder ear confession electricity.
CN201180053270.3A 2010-10-13 2011-10-12 For electrical management device and the method for distributing antenna system medium-long range antenna element Expired - Fee Related CN103329482B (en)

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