CN101340647A - Wireless access system and carrier moving method based on centralized base station - Google Patents

Abstract

The invention discloses a wireless access system based on a centralized base station, which comprises a centralized base station and a remote antenna unit. The centralized base station is used for the dynamic configuration or virtual carrier frequency shifting of a carrier frequency signal, and the carrier frequency signal is modulated and multiplexed to light wave and then the light wave is multiplexed to an optical fiber link; the remote antenna unit is connected with the centralized base station by the optical fiber link as well as is used for extracting the carrier frequency signal modulated to an optical wave link and transmitting the signal to covered areas by a transmitting antenna. The invention also discloses a carrier frequency removal method based on the centralized base station. The system of the invention inherits the advantages of a distributed antenna system, enhances spectrum utilization rate and system capacity, and meanwhile realizes the functions of virtual carrier frequency removal and dynamic configuration of wireless resources.

Description

Wireless access system and carrier moving method based on the centralization base station

Technical field

The present invention relates to the wireless signal access technology in a kind of wireless communication field, specifically, relate to a kind of wireless access system and carrier moving method based on the centralization base station.

Background technology

Radio communication is one of most active branch in the communications field, also is the current communication technology with fastest developing speed.The proposition of honeycomb notion makes mobile communication obtain develop rapidly, no matter is first generation analog communication system, second generation digital communication system, or the network configuration that honeycomb fashion covers has all been continued to use in third generation communication.It is that the geographic area is divided into some sub-districts that honeycomb covers, and sets up a base station and antenna (situation that a shared base station, several sub-districts and antenna are also arranged) in each sub-district and covers whole sub-district, and all users in the sub-district insert this base station.This network configuration has played certain effect to improving the availability of frequency spectrum, its conventional method is to carry out cell splitting and cell sectorization, but, this method can only be alleviated the contradiction between limited frequency spectrum, power system capacity and the more and more higher communicating requirement to a certain extent, because, cell splitting and sectorization can not unrestrictedly go on, and this can bring a lot of problems such as interference, frequent switching.

Distributing antenna system is a kind of new Radio Access Network structure, and it separates the base station with antenna, utilize optical fiber that base station signal is sent to antenna, is transmitted into the user then.Compare with honeycomb, this system is the extension of abundant fiber resource as radio communication, a large amount of spaced antennas are more near the user, it is the sub-district at center with terminal use that several strip antennas around the user are formed one, like this, the transmitting power of antenna and terminal can reduce significantly, simultaneously, can improve the availability of frequency spectrum and power system capacity greatly.

Most signal processing is finished in the base station in the distributing antenna system, exists relatively-stationary relation between CF signal in the base station and the spaced antenna, and this has just weakened system to burst service peak emergency processing ability greatly.For example, hold megaevent in a certain zone, when theatrical performances etc. were movable, traffic carrying capacity was increased sharply, and power system capacity dynamically adjustment can cause conversation loss maybe can't insert.Usually the method that solves this class problem is that certain Radio Resource is reserved in the base station, and still, this can increase the equipment investment of operator greatly.

Summary of the invention

Technical problem solved by the invention provides a kind of wireless access system based on the centralization base station, has realized the dynamic-configuration with Radio Resource moved of virtual carrier frequency.

Technical scheme is as follows:

A kind of wireless access system based on the centralization base station comprises:

The centralization base station is used for that CF signal is carried out dynamic-configuration or virtual carrier frequency is moved, with the modulation of described CF signal be multiplexed on the light wave, and with described optical wavelength multiplexing to optical fiber link;

The far-end antenna element is connected with described centralization base station by optical fiber link, is used to extract the described CF signal that is modulated to the light wave link, via transmission antennas transmit to the zone that is covered.

Preferably, described optical fiber link comprises the WDM looped network that is connected successively, full fiber optic ring network, OADM optical node and optical fiber branch road.

Preferably, described far-end antenna element comprises optical fiber link interface unit, radio-frequency front-end and antenna system; Described optical fiber link interface unit is used for the light wave on the optical fiber link is downloaded to RAU, and perhaps, the uplink electrical signals that RAU is received changes light signal into, sends in the optical fiber link and goes; Radio-frequency front-end is used for descending baseband signal is modulated to radiofrequency signal, perhaps up radiofrequency signal is down-converted to baseband signal and forms radiofrequency signal, and described antenna system is used for radiofrequency signal is sent.

Preferably, described centralization base station comprises:

Baseband processing unit is used for changing CF signal into intermediate frequency or radiofrequency signal, and sends;

The radio frequency cross linkage unit is used for described intermediate frequency or radiofrequency signal are routed to the sub-carrier modulation unit;

The sub-carrier modulation unit is used to make the frequency of described intermediate frequency or radiofrequency signal to produce shift frequency formation modulating frequency, and described modulating frequency is multiplexed on one tunnel optical wavelength, and modulated process is subjected to the frequency shift keying unit monitors;

Optical cross-connection unit is used for optical wavelength is routed to the wavelength division multiplexing unit;

The wavelength division multiplexing unit is used to finish optical wavelength and arrives the multiplexing of described optical fiber link;

The control maintenance unit is used for administering and maintaining of system, and each module is carried out associated treatment when being used for virtual carrier frequency and moving;

The frequency shift keying unit is used to detect the accuracy of sub-carrier modulation cells modulate.

Preferably, described frequency shift keying unit receives the frequency modulation information of sub-carrier modulation unit described in the described control maintenance unit; Described frequency shift keying unit detects the carrier wave frequency information after the sub-carrier modulation cells modulate, modulation intelligence contrast with the sub-carrier modulation unit in itself and the described control maintenance unit, both are consistent to illustrate that the SCM modulation is correct, otherwise, illustrate that the carrier frequency after the SCM modulation exists mistake or error.

Preferably, described baseband processing unit comprises baseband pool, and dynamically is connected with described radio frequency cross linkage unit.

Preferably, described sub-carrier modulation unit has at least one optical wavelength input port and at least one optical wavelength output port; Described radio frequency cross linkage unit is used to finish the interconnection of described intermediate frequency or radiofrequency signal, CF signal is routed on the different optical wavelength input ports of described sub-carrier modulation unit; Described sub-carrier modulation unit is used for modulation behind the CF signal shift frequency and is multiplexed into one tunnel optical wavelength, and sends by different optical wavelength output ports.

Preferably, described optical cross-connection unit is routed to different wavelength division multiplexing unit according to service needed with different optical wavelength, realizes the dynamic assignment of optical wavelength.

Another technical problem solved by the invention provides a kind of carrier moving method based on the centralization base station, has realized the dynamic-configuration with Radio Resource moved of virtual carrier frequency.

Technical scheme is as follows:

A kind of carrier moving method based on the centralization base station comprises:

(1) dynamic-configuration is carried out with CF signal or virtual carrier frequency is moved in the centralization base station, then with the modulation of the CF signal behind the described shift frequency be multiplexed on the light wave, and is routed to different far-end antenna elements;

(2) described far-end antenna element extracts the described CF signal that is modulated on the light wave, via transmission antennas transmit to the zone that is covered.

Further, in the step (1), when virtual carrier frequency is moved, adopt and close on principle, described close on pay the utmost attention in the principle move sub-carrier modulation after the close CF signal of frequency, consider to move the CF signal of closing on the optical wavelength then, consider to move the CF signal of closing on the optical fiber link at last.

Further, in the step (1), the step that described virtual carrier frequency is moved comprises:

(11) the mapping relation table is carried out initialization and renewal;

(12) mapping relations of change CF signal and subcarrier shift frequency frequency make described CF signal produce shift frequency and form modulating frequency, and on the road optical wavelength that described modulating frequency modulation is also multiplexing; In shift frequency, modulation and multiplex process, observe described mapping relations table;

(13) with described optical wavelength multiplexing to optical fiber link, in multiplex process, observe the described relation table of penetrating.

Further, in the step (11), the described relation table of penetrating comprises CF signal tabulation, shift frequency list of frequency, modulating frequency tabulation, optical wavelength tabulation, the tabulation of interconnection optical wavelength, wavelength division multiplexing tabulation, optical fiber link tabulation.

Further, in the step (11), when disposing described mapping relations table, avoid on the optical wavelength carrying two or more, perhaps avoid two or more identical optical wavelength of carrying on an optical fiber with wireless carrier signal frequently.

Further, in the step (12), the radio frequency cross linkage unit is routed to the sub-carrier modulation unit by calling described CF signal tabulation with described CF signal; The described shift frequency list of frequency of sub-carrier modulation cell call, modulating frequency tabulation and optical wavelength tabulation with the shift frequency frequency effect in described CF signal and the sub-carrier modulation unit, produce modulating frequency, then this modulating frequency are modulated and are multiplexed on the optical wavelength; In the step (13), optical cross-connection unit calls the tabulation of interconnection optical wavelength, and the optical wavelength of carrying CF signal is carried out the interconnection of optical wavelength, and sends; Wavelength division multiplexing cell call wavelength division multiplexing tabulation, with described optical wavelength multiplexing to optical fiber link.

The proposition that the present invention proposes has been inherited the advantage of distributing antenna system based on the wireless access system of centralization base station, has improved the availability of frequency spectrum and power system capacity, simultaneously, has realized that virtual carrier frequency moves the function with the Radio Resource dynamic-configuration.All carrier frequency resources have been concentrated in the centralization base station, base band signal process and most of radio frequency processing are all finished in the centralization base station, radio frequency cross linkage unit, sub-carrier modulation unit, optical cross-connection unit and WDM unit are finished modulation, CF signal route and the light wave routing function of CF signal to light wave, realized not changing under the situation of centralization BTS hardware, according to business demand dynamic-configuration carrier frequency and adjustment Radio Resource.

Radio frequency cross linkage unit, sub-carrier modulation unit, optical cross-connection unit have been finished the routing function of CF signal to different far-end antenna elements, realized that virtual carrier frequency moves and the Radio Resource dynamic-configuration, can solve the demand of burst peak business network.Realize the optimization that Internet resources dispose based on the wireless access system of centralization base station, reduced the equipment investment of operator.Because virtual carrier moving function, the carrier frequency of whole network need not dispose by maximum telephone traffic, and only need dispose by average telephone traffic, thereby reduces investment outlay greatly.In addition,, strengthened system robustness, can realize non-maintainingly, saved maintenance cost because far-end antenna element equipment simplifies greatly.

In the wireless access system based on the centralization base station, the centralization base station maintenance is easy, dilatation convenient; The WDM fiber optic network is safe and reliable, and frequency resource is abundant; Far-end antenna element hardware device is simple, install easily, robustness is good, can realize non-maintaining.Virtual carrier frequency is moved the investment that technology is saved operator greatly, and whole system can be carried the wireless access system of multiple standard, as GSM, and CDMA, UMTS, BWA, WiMAX and WLAN etc.

Description of drawings

Fig. 1 is based on the schematic network structure of the wireless access system of centralization base station;

Fig. 2 is a centralization base station logic module structure schematic diagram;

Fig. 3 is a far-end antenna unit structure schematic diagram;

Fig. 4 is a centralization base station system structure chart;

Fig. 5 is that centralization base station virtual carrier frequency is moved schematic diagram.

Embodiment

The wireless access system based on the centralization base station that the present invention proposes has been inherited the advantage of distributing antenna system, improves the availability of frequency spectrum and power system capacity, simultaneously, has realized that virtual carrier frequency moves the function with the Radio Resource dynamic-configuration.

In the metropolitan area scope, only establish a big capacity centralization base station (CB based on the wireless access system of centralization base station, Centralized BTS) and some far-end antenna element (RAU, Remote AntennaUnit), both are connected by optical fiber, the common metropolitan area antenna distributed network (DAN, Distributed Antenna Network) of forming.The centralization base station is sent to distributed far-end antenna element to intermediate frequency or radiofrequency signal by optical fiber, and the sky bundle of lines CF signal by the far-end antenna element is transmitted into the overlay area again.(CB) concentrated all carrier frequency resources in the centralization base station, base band signal process and most of radio frequency processing are all finished in the centralization base station, by CF signal being arrived modulation, CF signal route and the light wave routing function of light wave, realized that virtual carrier frequency moves and the Radio Resource dynamic-configuration, solved the demand of burst peak business network.

With reference to the accompanying drawings, the preferred embodiments of the present invention are described in detail.

As shown in Figure 1, in a bigger geographic area or metropolitan area scope, wireless access system based on the centralization base station comprises a centralization base station (CB, Centralized BTS) and some far-end antenna elements, be connected by optical fiber link between CB and the RAU, form distributed metropolitan area aerial network.Optical fiber link comprises WDM looped network (WDM all fiber ring), full fiber optic ring network, OADM (optical add-drop multiplexer) optical node and optical fiber branch road.The far-end antenna element is by the optical wavelength on the optical fiber link at optical interface (selecting FC for use at this optical interface) download OADM node place, carry out opto-electronic conversion, then, extract the CF signal that is modulated on the light wave by band pass filter, and carry out processing such as frequency conversion, finish the emission of CF signal at last through antenna.Up direction, the signal of RAU receiving terminal after down-conversion and filtering, is a light signal with conversion of signals, amplifying through EDFA, is transferred among the CB by optical fiber link, carries out processing such as demodulation.

At down direction, the optical fiber link interface unit is downloaded certain or some optical wavelength from optical fiber link, and changes light signal into the signal of telecommunication by PD (photodiode).Band pass filter BPF leaches the carrier signal that RAU needs from the signal of telecommunication, pass through the upconversion process of frequency mixer and the processing and amplifying of power amplifier then, launches from antenna; Up direction, RAU receives wireless signal from antenna, after the low noise amplifier amplification, carry through the tuning Filtering Processing of selecting ripple and band pass filter of frequency mixer, obtain up rf signal, LD (laser diode) changes the signal of telecommunication into light signal, and is modulated on the light wave, sends to CB by optical fiber link at last.

RAU is simple in structure, and radio-frequency front-end is only relevant with frequency with antenna system, therefore, adopts different radio frequency front end and antenna system just can support the different radio standard, as GSM, CDMA, UMTS, WLAN, BWA, WiMAX etc.Adopt the radio-frequency front-end and the antenna system in broadband can support multiple wireless standard simultaneously.

In traditional cellular network architecture, one or several sub-district is responsible in a base station, needs a plurality of base stations to finish comprehensive covering in the metropolitan area scope or in the bigger geographic area.By comparison, the centralization base station is equivalent to all base station resources are concentrated in together, and forms a jumbo base station, and the far-end antenna element is responsible for covering a little zone, and a plurality of far-end antenna elements form distributed overlay network.The far-end antenna element is connected to the centralization base station by the WDM optical networking, downloads different optical wavelength at optical network node OADM place, distributes the wireless carrier signal that is carried on this wavelength by optical fiber Zhi Luxiang far-end antenna element then.

Down direction, all CF signal are sent by a centralization base station, are sent to described far-end antenna element through optical fiber, the far-end antenna element with the signal demodulation after, to the institute overlay area, the up direction process is in contrast via transmission antennas transmit.

As shown in Figure 2, centralization base station (CB) mainly comprise baseband processing unit (BBU, BaseBand Unit), radio frequency cross linkage unit (RXC, Radio Cross-Connection), sub-carrier modulation unit (SCM, Sub-Carrier Multiplexing), optical cross-connection unit (OXC, OpticalCross-Connection), wavelength division multiplexing unit (WDM, Wavelength DivisionMultiplexing), control maintenance unit (CMM, Control Maintenance Module), frequency shift keying unit (FSK, Frequency Shift key).

FSK mainly is responsible for the monitoring work of SCM modulation, and CMM is the frequency modulation information of SCM, and for example the frequency bandwidth of the frequency of carrier wave, adjacent carrier etc. sends to FSK; FSK detects the carrier wave frequency information after the modulation, and with its SCM modulation intelligence contrast with CMM, both consistent SCM that illustrate modulate correctly, otherwise, illustrate that the carrier frequency after SCM modulates exists mistake or error.Can monitor the accuracy of SCM modulation by FSK.

Wherein, baseband processing unit (BBU, Base Band Unit) is mainly used in Base-Band Processing and the part radio frequency processing of finishing all CF signal, comprises baseband processing module and radio frequency processing module.Baseband processing module is with the work of resource sharing mode, and promptly baseband processing module forms a resource pool, dynamically is connected with the radio frequency processing module, and from baseband processing unit output is analog intermediate frequency or radiofrequency signal.It is that baseband signal with descending is modulated to radiofrequency signal that the radio frequency processing module mainly acts on, and perhaps up radiofrequency signal is down-converted to baseband signal.

Radio frequency cross linkage unit (RXC, Radio Cross-Connection) is finished analog intermediate frequency or the radiofrequency signal routing function to sub-carrier modulation unit (SCM).Sub-carrier modulation unit (SCM) comprises shift frequency module, modulation and Multiplexing module, and wherein, the effect of shift frequency module is to make the CF signal frequency of input produce shift frequency, has the local modulating frequency that is no less than the CF signal number; Modulation and Multiplexing module are modulated to one or more CF signal through shift frequency on the optical wavelength, and modulated process is monitored by FSK.Optical cross-connection unit (OXC, Optical Cross-Connection) is finished the cross connect function of different optical wavelength to the WDM unit.The multiplexing function of optical wavelength to optical fiber link finished in wavelength division multiplexing unit (WDM, Wavelength DivisionMultiplexing).

Control maintenance unit (CMM, Control Maintenance Module) is responsible for administering and maintaining of CB system, to each module be configured, monitoring, troubleshooting etc.The associated treatment of each module when particularly being responsible for virtual carrier frequency and moving, for example cross interconnected, the SCM modulation management of radiofrequency signal, light Cross module wavelength routing management etc.

The interconnection, radiofrequency signal frequency displacement processing, frequency-shift signaling that exist radiofrequency signal in CB inside are to the modulation multiplex of light wave, the various procedures such as interconnection of light signal.For reasonable disposition and management CB, at CMM or based on the network management system stored mapping relations table T of centralization base station access network, this is penetrated relation table T and comprises following parameter list:

CF signal tabulation S _n, CF signal is meant the analog intermediate frequency or the radiofrequency signal of BBU output, n is the CF signal sequence number;

The shift frequency list of frequency f of sub-carrier modulation unit _n, the shift frequency frequency makes CF signal generation frequency displacement, obtains the sub-carrier modulation list of frequency, and n is the sequence number of shift frequency frequency;

The modulating frequency tabulation f of sub-carrier modulation unit _Sn, f _SnWith f _nCorresponding one by one, sn is the sequence number of modulating frequency;

Optical wavelength tabulation λ _m, m is the sequence number of optical wavelength;

Interconnection optical wavelength tabulation λ _Sm, be light wavelength lambda _mThrough the light wave of exporting behind the optical cross-connection unit, sm is the optical wavelength sequence number;

The WDM WDM that tabulates _l, l is the sequence number of WDM unit;

Optical fiber link tabulation L _k, k is the optical fiber link sequence number, the WDM unit is corresponding one by one with optical fiber link;

The far-end antenna element ID R that tabulates _p, p is far-end antenna element ID number, far-end antenna element and optical fiber link exist fixedlys connected relation.

The mapping relations table T of parameter list has reflected the radio-resource-configuration situation of centralization base station access system.It has comprised S _nIn CF signal to f _nThe routing relation of middle shift frequency frequency, f _SnTo λ _mModulation and multiplexing relation, λ _mTo λ _SmInterconnection relation, λ _SmTo WDM _lMultiplexing relation, WDM _lWith L _kCorresponding relation, optical fiber link L _kTo far-end antenna element R _pAnnexation.Mapping relations table T has finally set up the radio carrier frequency signal to far-end antenna element mapping relations.

During configuration mapping relations table, must avoid two kinds of situations: carrying is two or more with the frequency wireless carrier signal on the first, one optical wavelength; The second, be two or more identical optical wavelength of carrying on an optical fiber.In order to reach this purpose, taked validity checking mechanism based on the wireless access system of centralization base station, before configuration or upgrading mapping relations table T, the mapping relation table has been examined by CMM or network management system, one of above-mentioned two kinds of situations occurring is considered as illegally forbidding resource distribution.

In the wireless access system based on the centralization base station, the CF signal emission receives and virtual carrier frequency is moved by following process realization:

The radio frequency cross linkage unit is by calling CF signal tabulation S _n, CF signal is routed to the sub-carrier modulation unit; Sub-carrier modulation cell call shift frequency list of frequency f _n, modulating frequency tabulation f _SnWith optical wavelength tabulation λ _m, with CF signal S _nWith the shift frequency frequency f in the sub-carrier modulation unit _nEffect produces modulating frequency f _Sn, modulate and be multiplexed into light wavelength lambda then _mOn.Subcarrier shift frequency list of frequency f _nIn the frequency number be no less than CF signal tabulation S _nIn the CF signal number, f _nIn frequency have nothing in common with each other, purpose is to guarantee the modulating frequency f that produces after both mixing _SnHave nothing in common with each other.Subcarrier is to the multiplexing CF signal tabulation S that meets of light wave _nTo optical wavelength tabulation λ _mMapping relations.By software control CF signal is multiplexed on the different optical wavelength, thereby realizes CF signal moving on the carrying optical wavelength.

Optical cross-connection unit calls interconnection optical wavelength tabulation λ _Sm, will carry the light wavelength lambda of CF signal _mCarry out the interconnection of optical wavelength, output light wavelength λ _SmThe wavelength division multiplexing cell call WDM WDM that tabulates _l, with λ _SmBe multiplexed into WDM _iOn the unit, WDM _iThe unit is connected to optical fiber link L _kOn.Can make the optical wavelength multiplexing that is carrying CF signal by software control to different WDM unit, thereby realize optical wavelength moving at optical fiber link.

Optical fiber link L _kWith far-end antenna element R _pExist to be fixedly coupled relation, optical fiber link comprises the full fiber optic ring network of WDM, OADM optical node and optical fiber branch road (Fig. 1).The far-end antenna element is by downloading optical fiber link L at OADM node place _kOn light wavelength lambda _Sm, perhaps download the light wavelength lambda that process is amplified by optical interface (FC) _Sm, carry out opto-electronic conversion, then, extract the CF signal be modulated on the light wave, and carry out processing such as frequency conversion by band pass filter, finish the emission of CF signal at last through antenna.

In whole process, the interconnection of the interconnection of CF signal, frequency conversion, sub-carrier modulation, light signal and the multiplexing parameter maps relation table T that strictly observes are to guarantee the correctness of radio carrier frequency signal transmitting and receiving and carrier moving.Pass through said process, centralization base station radio connecting system can be finished CF signal and focus on and distributed emission, the more important thing is, under the condition that does not change hardware configuration, the realization virtual carrier frequency is moved, and makes the wireless access system based on the centralization base station become dynamic distributed system.

In addition, for of the requirement of reduction system to the technical sophistication degree of equipment, particularly reduce the performance requirement of OADM in far-end antenna element median filter and the WDM looped network, when virtual carrier frequency is moved, employing closes on principle, promptly pay the utmost attention to and move the close CF signal of frequency after the sub-carrier modulation, consider to move the CF signal of closing on the optical wavelength then, consider to move the CF signal of closing on the optical fiber link at last.

As shown in Figure 3, the far-end antenna element is mainly used in finishes light/electricity conversion (PD, Photo Detector)/(LD, Laser Diode), mainly comprises optical fiber link interface unit, radio-frequency front-end and antenna system (Antenna) etc.The optical fiber link interface unit is responsible for the light wave on the optical fiber link is downloaded to RAU, and perhaps, the uplink electrical signals that RAU is received changes light signal into, sends in the optical fiber link and goes.The optical fiber link interface unit comprises optical circulator, photodiode (PD), laser diode (LD), fiber amplifier devices such as (EDFA).Radio-frequency front-end is used for descending baseband signal is modulated to radiofrequency signal, perhaps up radiofrequency signal is down-converted to baseband signal, comprises filter (BPF), frequency mixer, power amplifier (PA), low noise amplifier (LNA) etc.Antenna system is used for sending or received RF signal.

In order to save optical fiber link, to avoid producing than long time delay between the CF signal transmitting-receiving, centralization base station and far-end antenna element all utilize optical circulator that the receiving and transmitting signal of one road carrier frequency is multiplexed on the optical fiber link.

With reference to shown in Figure 4, the system configuration and the handling process of CF signal in center base station of centralization base station is described in detail.

Resource pool of finishing Base-Band Processing of the inner formation of baseband processing unit (BBU), the dynamic process CF signal, from baseband processing unit (BBU) output is analog intermediate frequency or radio frequency (IF/RF) signal.The IF/RF signal is input to the RXC unit, and the IF/RF signal can be routed to different output ports from input port in RXC.Then, the IF/RF signal enters the SCM unit, local shift frequency frequency is carried out the shift frequency processing to CF signal in the SCM, obtain the SCM modulating frequency, then, with the CF signal modulation multiplex behind the shift frequency on optical wavelength, can correctly demodulation CF signal in order to ensure the far-end antenna element, here need to guarantee that the modulating frequency that is carried on the same wavelength has nothing in common with each other, comprise photodiode (PD in the SCM unit, Photo Detector), laser diode (LD, Laser Diode), descending pass port filter (PFDL, pass fiter of downlink).Lightwave signal enters the OXC unit, and in the OXC unit, optical wavelength is carried out interconnection, and purpose is that every road optical wavelength can both be exported from the different output ports of OXC.The OXC output port directly is connected with WDM, and WDM to optical fiber link, sends to the far-end antenna element to the optical wavelength multiplexing of input after light amplification.In OXC and WDM unit, must guarantee to occur in the optical fiber link two-way and the above identical optical wavelength of two-way.Signal processing recited above is finished under the CMM unit monitors, and satisfies the legitimacy requirement of parameter maps relation table T.

In order to realize that one road signal transmitting and receiving realizes in an optical fiber link, add an optical circulator one group of back, WDM unit of being responsible for receiving and dispatching.

In the centralization base station, CF signal by frequency division multiplexing on optical wavelength, light wave by wavelength division multiplexing to optical fiber link.Like this, distinguish wavelength signals with tunable OADM,, realize the smooth transmission of CF signal to the far-end antenna element at the radio carrier frequency signal of remote terminal far-end antenna element by filter differentiation and download different frequency at the optical network node place.

Can realize under the hardware devices circumstances that virtual carrier frequency moves not changing based on the wireless access system of centralization base station, satisfy the professional requirement that changes radio-resource-configuration.

With reference to shown in Figure 5, the shift frequency process is described in detail.

Technical solution of the present invention realizes virtual move of CF signal between different far-end antenna elements by the radio frequency cross linkage unit in the centralization base station, sub-carrier modulation unit, optical cross-connection unit and WDM unit under the situation that does not change the configuration of centralization BTS hardware.

When initial configuration, the centralization base station is to the CF signal S that tabulates _n, the sub-carrier modulation unit shift frequency list of frequency f _n, modulating frequency tabulation f _Sn, optical wavelength tabulation λ _m, interconnection optical wavelength tabulation λ _Sn, WDM unit list WDM _l, optical fiber link tabulation L _k, far-end antenna element tabulation R _pAnd the mapping relations table T between each parameter list carries out initialization, and mapping relations table T is stored in the control maintenance unit or network management system of centralization base station.Footnote n, sn, m, l, k and the p of parameter list symbol represents parameter sequence number in the tabulation respectively, and the mapping relations table has reflected the corresponding relation of parameter between each tabulation.

Before virtual carrier frequency is moved, the control maintenance unit of centralization base station or network management system calculating are also upgraded described tabulation and mapping relations table, carrying two and plural identical subcarrier frequency on the optical wavelength avoided in assurance, avoids carrying on the optical fiber optical wavelength identical more than two and two.Move according to new described tabulation and mapping relations table enforcement virtual carrier frequency.

CF signal S _nBe routed to the sub-carrier modulation unit by the radio frequency cross linkage unit, with the shift frequency frequency f in the sub-carrier modulation unit _nEffect produces the sub-carrier modulation frequency f _Sn, modulate and be multiplexed into light wavelength lambda then _mOn.During carrier moving, by changing CF signal S _nWith subcarrier shift frequency frequency f _nMapping relations realize CF signal moving on the different bearer optical wavelength.Carrying the light wavelength lambda of CF signal _mBy output light wavelength behind the optical cross-connection unit is λ _Sm, λ _SmBe connected to WDM _lOn the unit, then, through WDM _lBe multiplexed into optical fiber link L _kOn.When virtual carrier frequency is moved, change light wavelength lambda by the control optical cross-connection unit _mWith λ _SmBetween interconnection relation, just can realize optical wavelength moving at optical fiber link.

Optical fiber link L _kWith far-end antenna element R _pHave corresponding relation, the far-end antenna element can be discerned and demodulation L _kOn CF signal, be transmitted into the overlay area after the processing.

By said process, CF signal can dynamically be moved on wavelength, optical fiber link and far-end antenna element.

Be example with one tunnel CF signal S1 below, illustrate that a concrete virtual carrier frequency moves process.

Before virtual carrier frequency was moved, radio carrier frequency signal S1 was transferred to ID number by path Line1 and is the far-end antenna element of R1.S1 is sent by the BBU unit, through the f of RXC elements exchange to the sub-carrier modulation unit ₁Port, f ₁Be the shift frequency frequency of sub-carrier modulation, S1 is through f ₁Shift frequency handle after, frequency becomes f _S1, f _S1Be the modulating frequency of sub-carrier modulation unit, f _S1Radiofrequency signal is modulated onto light carrier λ ₁On, λ ₁Be multiplexed into WDM1 and go up, transmit far-end antenna element R1 through optical fiber link L1.Far-end antenna element R1 downloads λ by opto-electronic conversion and band pass filter ₁On CF signal S1, through after the frequency conversion, be transmitted into the overlay area.

The transmission path Line1 of S1 is as follows among the mapping relations table T:

$\mathrm{<figure-callout\; id="1"\; label="S"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">S</figure-callout>}1\&LeftRightArrow;{\mathrm{<figure-callout\; id="1"\; label="f"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">f</figure-callout>}}_1\&LeftRightArrow;f_{s1}\&LeftRightArrow;{\mathrm{\&lambda;}}_1\&LeftRightArrow;{\mathrm{\&lambda;}}_{\mathrm{<figure-callout\; id="1"\; label="s"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">s</figure-callout>}1}\&LeftRightArrow;{\mathrm{<figure-callout\; id="1"\; label="WDM"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">WDM</figure-callout>}}_1\&LeftRightArrow;{\mathrm{<figure-callout\; id="1"\; label="L"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">L</figure-callout>}}_1\&LeftRightArrow;\mathrm{<figure-callout\; id="1"\; label="R"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">R</figure-callout>}1$

Have mapping relations between CF signal sequence number and the far-end antenna element ID number, and mapping satisfies the legitimacy requirement, this has just finished transmitting and receiving of CF signal.

After if virtual carrier frequency is moved, the transmission path of S1 changes Line2 into, and the parameter corresponding relation in the mapping relations table is as follows:

$\mathrm{<figure-callout\; id="1"\; label="S"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">S</figure-callout>}1\&LeftRightArrow;{\mathrm{<figure-callout\; id="5"\; label="f"\; filenames="A20071012298200211.png"\; state="\{\{state\}\}">f</figure-callout>}}_5\&LeftRightArrow;f_{s5}\&LeftRightArrow;{\mathrm{\&lambda;}}_i\&LeftRightArrow;{\mathrm{\&lambda;}}_{\mathrm{si}}\&LeftRightArrow;{\mathrm{WDM}}_i\&LeftRightArrow;L_i\&LeftRightArrow;\mathrm{Ri}$

Radio carrier frequency signal S1 sends to far-end antenna element Ri, and mapping relations satisfy the legitimacy requirement.

CF signal S1 moves in the process, does not change the hardware configuration of centralization base station, but has realized the migration of CF signal on different wave length and different fiber link by software control RXC, SCM and OXC.

Claims (14)

1, a kind of wireless access system based on the centralization base station is characterized in that, comprising:

The centralization base station is used for that CF signal is carried out dynamic-configuration or virtual carrier frequency is moved, with the modulation of described CF signal be multiplexed on the light wave, and with described optical wavelength multiplexing to optical fiber link;

The far-end antenna element is connected with described centralization base station by optical fiber link, is used to extract the described CF signal that is modulated to the light wave link, via transmission antennas transmit to the zone that is covered.

2, the wireless access system based on the centralization base station according to claim 1 is characterized in that, described optical fiber link comprises the WDM looped network that is connected successively, full fiber optic ring network, OADM optical node and optical fiber branch road.

3, the wireless access system based on the centralization base station according to claim 1 is characterized in that, described far-end antenna element comprises optical fiber link interface unit, radio-frequency front-end and antenna system; Described optical fiber link interface unit is used for the light wave on the optical fiber link is downloaded to RAU, and perhaps, the uplink electrical signals that RAU is received changes light signal into, sends in the optical fiber link and goes; Radio-frequency front-end is used for descending baseband signal is modulated to radiofrequency signal, perhaps up radiofrequency signal is down-converted to baseband signal and forms radiofrequency signal, and described antenna system is used for radiofrequency signal is sent.

4, the wireless access system based on the centralization base station according to claim 1 is characterized in that, described centralization base station comprises:

Baseband processing unit is used for changing CF signal into intermediate frequency or radiofrequency signal, and sends;

The radio frequency cross linkage unit is used for described intermediate frequency or radiofrequency signal are routed to the sub-carrier modulation unit;

The sub-carrier modulation unit is used to make the frequency of described intermediate frequency or radiofrequency signal to produce shift frequency formation modulating frequency, and described modulating frequency is multiplexed on one tunnel optical wavelength, and modulated process is subjected to the frequency shift keying unit monitors;

Optical cross-connection unit is used for optical wavelength is routed to the wavelength division multiplexing unit;

The wavelength division multiplexing unit is used to finish optical wavelength and arrives the multiplexing of described optical fiber link;

The control maintenance unit is used for administering and maintaining of system, and each module is carried out associated treatment when being used for virtual carrier frequency and moving;

The frequency shift keying unit is used to detect the accuracy of sub-carrier modulation cells modulate.

5, the wireless access system based on the centralization base station according to claim 4 is characterized in that, described frequency shift keying unit receives the frequency modulation information of sub-carrier modulation unit described in the described control maintenance unit; Described frequency shift keying unit detects the carrier wave frequency information after the sub-carrier modulation cells modulate, modulation intelligence contrast with the sub-carrier modulation unit in itself and the described control maintenance unit, both are consistent to illustrate that the SCM modulation is correct, otherwise, illustrate that the carrier frequency after the SCM modulation exists mistake or error.

6, the wireless access system based on the centralization base station according to claim 4 is characterized in that, described baseband processing unit comprises baseband pool, and dynamically is connected with described radio frequency cross linkage unit.

7, the wireless access system based on the centralization base station according to claim 4 is characterized in that, described sub-carrier modulation unit has at least one optical wavelength input port and at least one optical wavelength output port; Described radio frequency cross linkage unit is used to finish the interconnection of described intermediate frequency or radiofrequency signal, CF signal is routed on the different optical wavelength input ports of described sub-carrier modulation unit; Described sub-carrier modulation unit is used for modulation behind the CF signal shift frequency and is multiplexed into one tunnel optical wavelength, and sends by different optical wavelength output ports.

8, the wireless access system based on the centralization base station according to claim 4 is characterized in that, described optical cross-connection unit is routed to different wavelength division multiplexing unit according to service needed with different optical wavelength, realizes the dynamic assignment of optical wavelength.

9, a kind of carrier moving method based on the centralization base station comprises:

(1) dynamic-configuration is carried out with CF signal or virtual carrier frequency is moved in the centralization base station, then with the modulation of the CF signal behind the described shift frequency be multiplexed on the light wave, and is routed to different far-end antenna elements;

(2) described far-end antenna element extracts the described CF signal that is modulated on the light wave, via transmission antennas transmit to the zone that is covered.

10, the carrier moving method based on the centralization base station according to claim 9, it is characterized in that, in the step (1), when virtual carrier frequency is moved, adopt and close on principle, described close on pay the utmost attention in the principle move sub-carrier modulation after the close CF signal of frequency, consider to move the CF signal of closing on the optical wavelength then, consider to move the CF signal of closing on the optical fiber link at last.

11, the carrier moving method based on the centralization base station according to claim 9 is characterized in that, in the step (1), the step that described virtual carrier frequency is moved comprises:

(11) the mapping relation table is carried out initialization and renewal;

(12) mapping relations of change CF signal and subcarrier shift frequency frequency make described CF signal produce shift frequency and form modulating frequency, and on the road optical wavelength that described modulating frequency modulation is also multiplexing; In shift frequency, modulation and multiplex process, observe described mapping relations table;

(13) with described optical wavelength multiplexing to optical fiber link, in multiplex process, observe the described relation table of penetrating.

12, the carrier moving method based on the centralization base station according to claim 11, it is characterized in that, in the step (11), the described relation table of penetrating comprises CF signal tabulation, shift frequency list of frequency, modulating frequency tabulation, optical wavelength tabulation, the tabulation of interconnection optical wavelength, wavelength division multiplexing tabulation, optical fiber link tabulation.

13, the carrier moving method based on the centralization base station according to claim 11, it is characterized in that, in the step (11), when disposing described mapping relations table, avoid the two or more frequency together of carrying wireless carrier signal on the optical wavelength, perhaps avoid two or more identical optical wavelength of carrying on an optical fiber.

14, the carrier moving method based on the centralization base station according to claim 12 is characterized in that, in the step (12), the radio frequency cross linkage unit is routed to the sub-carrier modulation unit by calling described CF signal tabulation with described CF signal; The described shift frequency list of frequency of sub-carrier modulation cell call, modulating frequency tabulation and optical wavelength tabulation with the shift frequency frequency effect in described CF signal and the sub-carrier modulation unit, produce modulating frequency, then this modulating frequency are modulated and are multiplexed on the optical wavelength; In the step (13), optical cross-connection unit calls the tabulation of interconnection optical wavelength, and the optical wavelength of carrying CF signal is carried out the interconnection of optical wavelength, and sends; Wavelength division multiplexing cell call wavelength division multiplexing tabulation, with described optical wavelength multiplexing to optical fiber link.

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