CN102271407B - Method for dispatching terminal - Google Patents
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Abstract
The invention discloses a wireless access network system, a terminal, a data transmission method and a method for dispatching terminals. The wireless access network system comprises a data broadcasting subsystem, a frequency division duplex (FDD) subsystem and a time division duplex (TDD) subsystem, wherein the data broadcasting subsystem comprises a first emission channel; the FDD subsystem comprises a second receiving channel and a second emission channel; the TDD subsystem comprises a third subsystem and a third emission channel; the first emission channel of the data broadcasting subsystem is configured to work on a first frequency band; the second emission channel of the FDD subsystem is configured to work on a second frequency band; and the third emission channel and the third receiving channel of the TDD subsystem are configured to work on the third frequency band, wherein the second frequency band is mounted between the first frequency band and the third frequency band and is adjacent to the first frequency band and the third frequency band. According to the technical scheme disclosed by the invention, the use frequency spectrum of the wireless access network is configured to improve the use ratio of the frequency spectrum.
Description
The present invention is: on September 4th, 2008, application number is: 200810215040.2, and denomination of invention is: the dividing an application of the patent of invention of the method > > of < < wireless access network system, terminal, data transmission method, dispatch terminal.
Technical field
The present invention relates to the communications field, relate in particular to a kind of method of dispatch terminal.
Background technology
Third generation partner program (3rd Generation Partnership Project, referred to as 3GPP) at Long Term Evolution (the Long Term Evolution of its formulation, referred to as LTE) in system standard, comprise following system: with time division duplex (Time Division Duplexing, referred to as TDD) system of mode work, with Frequency Division Duplexing (FDD) (Frequency Division Duplex, referred to as FDD) system of mode work, multimedia broadcast multi-broadcasting business system (Multi-cast and Broadcast Multimedia System with the work of private downlink carrier mode, referred to as MBMS).
At present, in 3GPP system, according to the disturbed condition of adjacent channel, the TDD frequency spectrum of 1900-1920MHz, 2010-2025MHz, tri-frequency ranges of 2570-2620MHz is analyzed for the feasibility of MBMS, and analysis result is: terminal receives MBMS and is infeasible at 1920-1980MHz band transmission MBMS at 1900-1920MHz frequency band simultaneously; Terminal receives MBMS and launches MBMS at 1920-1980MHz at 1900-1910MHz frequency band is simultaneously feasible, but needs 10MHz protection bandwidth by way of compensation; Terminal simultaneously receives MBMS and is feasible at 1920-1980MHz band transmission MBMS at 2010-2025MHz frequency band.
In addition, 3GPP advises (the International Telecommunication Union of International Telecommunications Union, referred to as ITU) take 3GPP LTE TDD/FDD and as basis, carry out the standard formulation of IMT-Advanced, the IMT-Advanced of ITU name is referred to as LTE-Advanced in 3GPP.LTE-Advanced system is the transmission rate that reaches 1Gbps, need to use the bandwidth of 100MHz, in actual spectrum planning, the frequency bandwidth that accumulative total is distributed to mobile communication system use has reached hundreds of million Hz, but, these frequency bands exist with discontinuous state, for example, in 3G (Third Generation) Moblie, extended frequency band 2500~2690MHz is divided into the FDD uplink band of 70MHz bandwidth, the FDD band downlink of 70MHz bandwidth and the TDD frequency range of 50MHz bandwidth, in order to obtain the transmission bandwidth of 100MHz, IMT-Advanced system merges the frequency band of several interruptions or assemble (aggregation) and gets up to use.
Fig. 1 a shows the schematic diagram of the spectrum aggregation method of prior art, as shown in Fig. 1 (a), in order to improve transmission rate, a plurality of frequency ranges of terminal Integrated using are carried out the transmission of data, at present mainly by carrier aggregation, realize the use to the plurality of frequency band, on each frequency band using at the same time, use an independent carrier wave or a plurality of carrier wave to transmit concurrently data.Particularly, each community all provides a plurality of continuous carrier waves, and take one of them carrier wave as main carrier, system provides BCH on this main carrier, UpPCH, DwPCH and other common signal channels, and only provide Traffic Channel at other carrier waves (also becoming auxiliary carrier wave), for the transmission of system information broadcast and the access of terminal.Fig. 1 b shows the frame structure schematic diagram of 3 carrier wave TD-SCDMA systems, shown in Fig. 1 b, carrier wave 1 is main carrier, carrier wave 2 and carrier wave 3 are auxiliary carrier wave, wherein, and after terminal accesses by main carrier, receive control module according to each carrier resource situation, the resource of unified distribution, terminal receiving enters main carrier or auxiliary carrier wave carries out the transmitting-receiving of business datum, and the terminal on auxiliary carrier wave need to periodically be tuned to main carrier receiving broadcasting information and carry out measurement of correlation.
In the collocation method of existing digital broadcasting frequency band, digit broadcasting system can take the frequency range (2010-2025MHz/1900-1920MHz) of tdd systems, but terminal is when frequency range 1900-1920MHz receives MBMS signal, the transmitting meeting of its up transmission channel on 1920MHz~1980MHz produces and disturbs the reception of MBMS, and, merge and use a plurality of discontinuous frequency bands can cause terminal complexity high, for example increase passage number and the power loss of terminal, therefore, in order to make terminal there is rational complexity and high spectrum efficiency, need to use the sequential frequency band of a large bandwidth as far as possible, but, the frequency spectrum of continuous large bandwidth is always very unobtainable, and in order to improve the service efficiency of frequency spectrum, a continuous large bandwidth frequency band need to be shared in the radio-frequency channel that belongs to different operators.The multi-carrier scheme that TD-SCDMA adopts is that the merging of the adjacent spectrum of carrier in same community or same WAP (wireless access point) is used, and in existing technical scheme, the method for the shared continuous large bandwidth frequency band of different operators does not provide concrete solution.
Summary of the invention
Consider that a kind of technology of the needs that exist in correlation technique solves different operators and shares the problem of a continuous large bandwidth frequency band and propose the present invention, for this reason, main purpose of the present invention is to provide a kind of method of wireless access network system, terminal, data transmission method and dispatch terminal, to address the above problem.
According to an aspect of the present invention, provide a kind of wireless access network system.
Wireless access network system according to the present invention comprises: comprise data broadcast subsystem, FDD subsystem and TDD subsystem, wherein, data broadcast subsystem comprises the first transmission channel, FDD subsystem comprises the second receive path and the second transmission channel, TDD subsystem comprises the 3rd receive path and the 3rd transmission channel, wherein, the first transmission channel of data broadcast subsystem is configured to work on the first frequency band; The second transmission channel of FDD subsystem is configured to work on the second frequency band, the 3rd transmission channel of TDD subsystem and the 3rd receive path are configured to work on the 3rd frequency band, wherein, the second frequency band is between the first frequency band and the 3rd frequency band, and adjacent with the 3rd frequency band with the first frequency band.
According to an aspect of the present invention, provide a kind of terminal.
Terminal according to the present invention comprises the first receive path, the second receive path, transmission channel, further, this terminal also comprises passage control module and channel capacity reporting module, wherein, channel capacity reporting module, for the channel parameters to network side reporting terminal by transmission channel; Passage control module, for the mode of operation that issues according to network side or according to the integrated mode of the business setting terminal radio frequency passage of the resource situation of terminal and terminal request.
According to another aspect of the present invention, provide a kind of data transmission method, the method is being used transmission or reception data on frequency band for terminal.
Data transmission method according to the present invention comprises: at least one receive path of terminal receives cell synchronous signal, scheduling controlling order on the ownership frequency band of terminal; The transmission channel of terminal sends service signal and channel detection signal using on frequency band.
According to another aspect of the present invention, provide a kind of data transmission method, the method first terminal and the second terminal are at non-attribution frequency band or use and on frequency band, carry out direct communication.
Data transmission method according to the present invention comprises: first terminal and the second terminal are by synchronizeing between the WAP (wireless access point) in its ownership frequency band and the Serving cell of this terminal, realize first terminal and participate in keeping synchronizeing between the second terminal of communication, wherein, first terminal and the second terminal receive the control signal from Serving cell WAP (wireless access point) on its ownership frequency band, and at its non-attribution frequency band or use and launch channel detection signal on frequency band.
According to an aspect of the present invention, provide a kind of method of dispatch terminal, the method is for dispatch terminal between different frequency bands.
According to the method for dispatch terminal of the present invention, comprise: network side is distributed to serially in time same terminal by the frequency spectrum resource on the first frequency band and the second frequency band and used; In very first time interval, network side is the resource on terminal distribution the first frequency band; In the second time interval, network side is the resource on terminal distribution the second frequency band; Wherein, within very first time interval and the second time interval are included in the duration of a wireless frame period.
By above-mentioned at least one technical scheme of the present invention, by the use frequency spectrum to wireless access network, be configured, solved the problem that different operators can not be shared a continuous large bandwidth frequency band, improved frequency spectrum service efficiency.
Accompanying drawing explanation
Accompanying drawing is used to provide a further understanding of the present invention, and forms a part for specification, for explaining the present invention, is not construed as limiting the invention together with embodiments of the present invention.In the accompanying drawings:
Fig. 1 a is the spectrum aggregation method schematic diagram according to correlation technique;
Fig. 1 b is according to the frame structure schematic diagram of 3 carrier wave TD-SCDMA systems of correlation technique;
Fig. 2 a is according to the structured flowchart of the wireless access network system of the embodiment of the present invention;
Fig. 2 b is the concrete structure block diagram according to the wireless access network system of the embodiment of the present invention;
Fig. 3 a is according to the structural representation one of the spectrum disposition of the wireless access network system shown in Fig. 2 a;
Fig. 3 b is according to the structural representation two of the spectrum disposition of the wireless access network system shown in Fig. 2 a;
Fig. 4 a is according to the concrete structure schematic diagram of the spectrum disposition of the wireless access network system shown in Fig. 3 a;
Fig. 4 b is according to the concrete structure schematic diagram of the spectrum disposition of the wireless access network system shown in Fig. 3 b;
Fig. 5 is according to the structural framing figure of the networking mode of the distributed heterogeneous wireless access network of the embodiment of the present invention and radio-frequency channel configuration mode;
Fig. 6 is the terminal structure frame diagram according to the embodiment of the present invention;
Fig. 7 is the concrete structure frame diagram according to the terminal of the embodiment of the present invention;
Fig. 8 is the instantiation schematic diagram according to the method for the dispatch terminal of the embodiment of the present invention;
Fig. 9 a is according to the method schematic diagram of the multiband dispatch terminal of the embodiment of the present invention target band;
Fig. 9 b is according to the method schematic diagram of the multiband dispatch terminal of two of the embodiment of the present invention target band;
Figure 10 is according to the method schematic diagram of the multiband dispatch terminal between two target band adjusting with resource occupation order of the embodiment of the present invention;
Figure 11 is according to the method schematic diagram of dispatch terminal between two non-paired frequency bands of the figure embodiment of the present invention.
Embodiment
Below in conjunction with accompanying drawing, describe the present invention in detail.
System embodiment
According to the embodiment of the present invention, provide a kind of wireless access network system.
Fig. 2 a is according to the structured flowchart of the wireless access network system of the embodiment of the present invention, as shown in Figure 2 a, according to the wireless access network system of the embodiment of the present invention, comprise data broadcast subsystem 202, FDD subsystem 204 and TDD subsystem 206, wherein, data broadcast subsystem comprises the first transmission channel 202T, FDD subsystem comprises the second receive path 204R and the second transmission channel 204T, TDD subsystem comprises the 3rd receive path 206R and the 3rd transmission channel 206T, wherein, the first transmission channel 202T of data broadcast subsystem is configured to work on the first frequency band, the second transmission channel 204T of FDD subsystem is configured to work on the second frequency band, the 3rd transmission channel 206T of TDD subsystem and the 3rd receive path 206R are configured to work on the 3rd frequency band, wherein, the second frequency band is between the first frequency band and the 3rd frequency band, and adjacent with described the 3rd frequency band with described the first frequency band.Above-mentioned digital broadcasting subsystem 202, FDD subsystem 204 and TDD subsystem 206 can be to belong to same operator, can be also the operators that belongs to different.
The technical scheme providing by the embodiment of the present invention, is configured the use frequency spectrum of wireless access network, and a continuous large bandwidth frequency band can be shared by a plurality of operators, has improved frequency spectrum service efficiency.
In addition, the second receive path 204R of FDD subsystem 204 is configured to work on the 4th frequency band, and wherein, the highest frequency of the 4th frequency band is lower than any the low-limit frequency in the first frequency band, the second frequency band, the 3rd frequency band.
Preferably, above-mentioned wireless access network system can further include frequency spectrum corporate management unit 208, Fig. 2 b shows the concrete structure block diagram according to the wireless access network system of the embodiment of the present invention, as shown in Figure 2 b, this frequency spectrum corporate management module 208 is connected to TDD subsystem 206, FDD subsystem 204 and data broadcast subsystem 202, wherein, this frequency spectrum corporate management module 208 comprises frequency spectrum logging modle, access control module and multiband scheduler module.
Wherein, the function of each module is as described below.
Frequency spectrum logging modle, for the frequency spectrum service condition of the radio-frequency channel on each frequency band of real time record;
Access control module, for the frequency spectrum service condition of the radio-frequency channel on each frequency band providing according to frequency spectrum logging modle, the access frequency band of designated terminal;
Multiband scheduler module, for determining that according to the frequency spectrum idle condition on different frequency bands terminal is to the use location of different frequency bands and service time, sends dispatch command to terminal.
Wherein, frequency spectrum corporate management unit can also comprise dynamic adjusting module, this dynamic adjusting module is for centre frequency and the bandwidth of operation of the first transmission channel 202T, the second transmission channel 204T, the 3rd transmission channel 206T are adjusted, and dynamically adjusting module can specifically comprise:
First adjusts submodule, for the required bandwidth of business of carrying according to digital broadcasting subsystem 202 and FDD subsystem 204, centre frequency and the bandwidth of operation of the first transmission channel 202T and the second transmission channel 204T is dynamically adjusted;
Second adjusts submodule, for the required bandwidth of business of carrying according to FDD subsystem 204 and TDD subsystem 206, centre frequency and the bandwidth of operation of the second transmission channel 204T and the 3rd transmission channel 206T is dynamically adjusted.
Particularly, Fig. 3 a and Fig. 3 b show the spectrum disposition structural representation of the heterogeneous radio access networks system shown in Fig. 2 a, below these two kinds of structures are described.
Structure one, as Fig. 3 a, the first transmission channel 202T of data broadcast subsystem 202 is configured to work on the first frequency band 301; The second transmission channel 204T of FDD subsystem 204 is configured to work on the second frequency band 302, the 3rd transmission channel 206T of TDD subsystem 206 and the 3rd receive path 206R are configured to work on the 3rd frequency band 303, wherein, the second frequency band 302 is positioned in the middle of the first frequency band 301 and the 3rd frequency band 303, the first frequency band 301 is positioned at the right side of the second frequency band 302, and the 3rd frequency band 303 is positioned at the left side of the second frequency band 302.Particularly, the first frequency band 301, the second frequency band 302 and the 3rd frequency band 303 can be according to the neighbouring relations shown in Fig. 4 a, be arranged within the scope of 698MHz~862MHz, the receive path 204R comprising as FDD subsystem 204 is operated on the 4th frequency band 304, wherein, the frequency range of the 4th frequency band 304 is 450MHz~470MHz.
Structure two, as Fig. 3 b, the first transmission channel 202T of data broadcast subsystem 202 is configured to work on the first frequency band 301; The second transmission channel 204T of FDD subsystem 204 is configured to work on the second frequency band 302, the 3rd transmission channel 206T of TDD subsystem 206 and the 3rd receive path 206R are configured to work on the 3rd frequency band 303, wherein, the second frequency band 302 is positioned in the middle of the first frequency band 301 and the 3rd frequency band 303, the first frequency band 301 is positioned at the left side of the second frequency band 302, and the 3rd frequency band 303 is positioned at the right side of the second frequency band 302.Particularly, the first frequency band 301, the second frequency band 302 and the 3rd frequency band 303 are according to the neighbouring relations shown in Fig. 4 b, be arranged within the scope of 698MHz~862MHz, the receive path 204 comprising as 3GPP LTE/LTE-A FDD subsystem 206 is operated on the 4th frequency band 304, and the frequency range of the 4th frequency band is 450MHz~470MHz.
In addition, the receive path 204R that FDD subsystem 204 comprises can be configured to work on the 4th frequency band, and the highest frequency of the 4th frequency band is lower than the low-limit frequency of above-mentioned the first frequency band 301, the second frequency band 302, the 3rd frequency band 303.
Fig. 5 shows the networking mode of distributed heterogeneous wireless access network and the structural framing figure of radio-frequency channel configuration mode, as shown in Figure 5, use the MBMS subsystem 202 of private downlink carrier, the form of the distributed base station of FDD subsystem 204 and TDD subsystem 206 is carried out networking, in this distributed base station, frequency spectrum corporate management unit 208 is by optical fiber and remote radio unit (RRU) 501, 502a, 502b, 502c, 502d realizes communication and Synchronization Control, wherein, remote radio unit (RRU) 501 comprises the reception/transmission channel 204R/T in FDD subsystem 204, and the transmission channel 202T in the MBMS subsystem 202 of use private downlink carrier, remote radio unit (RRU) 502 comprises the reception/transmission channel 206R/T in TDD subsystem 206, under the control of frequency spectrum corporate management unit 208, the radio frames of remote radio unit (RRU) 501 and 502 transmittings keeps synchronous in time, wherein, the antenna that the radio-frequency channel of MBMS subsystem 202 is identical with the common use in radio-frequency channel of FDD subsystem 204.
Frequency band in wireless access network system can be divided into ownership frequency band and non-attribution frequency band, below ownership frequency band and non-attribution frequency band be described.
Ownership frequency band: the frequency band that the relatively-stationary mode of take configures as radio-frequency channel is referred to as the ownership frequency band of radio-frequency channel, for example, a plurality of reception/transmission channel 206R/T of a plurality of TDD subsystems 206 are configured in one section of continuous frequency spectrum for up-downgoing transmission by its frequency band in relatively-stationary mode, the transmission channel 202T of a plurality of FDD subsystems 204 or a plurality of FDD or receive path 204R by its frequency band with relatively-stationary mode be configured in one section continuous in frequency spectrum descending or up-downgoing transmission, the data broadcast subsystem 202 of a plurality of use private downlink carriers or transmission channel 202T are configured in one section of continuous frequency spectrum for downlink transfer by its frequency band in relatively-stationary mode.Radio-frequency channel provides as lower channel to terminal on its ownership frequency band: CBCH, uplink synchronous channel, descending synchronous signal channel and intercarrier scheduling controlling channel.And the ownership frequency band of the radio-frequency channel of each subsystem is the licensed band of this subsystem.
Non-attribution frequency band: outside the ownership frequency band that radio-frequency channel is used, and be called the non-attribution frequency band of radio-frequency channel with the frequency band that ownership frequency band forms sequential frequency band, radio-frequency channel is except can dynamically being used ownership frequency band, can also dynamically use non-attribution frequency band, radio-frequency channel can provide traffic channel information, measure channel information to the terminal being scheduled on its non-attribution frequency band.Wherein, non-attribution frequency band can comprise one of at least following: the non-paired frequency band that the paired frequency band that license is used to FDD system, license are used to TDD system, license to the partial-band in the frequency spectrum of terrestrial broadcast system, exempt from the partial-band in licensed band.
In above-mentioned heterogeneous radio access networks system, between the radio frames of each radio-frequency transmissions passage transmitting, want the retention time synchronous, for example, can keep in time synchronous by following two kinds of modes:
Mode one: the original position of the radio frames of different radio frequency passage transmitting is alignd in time when leaving Antenna aperture, upper alignment of time here refer to the original position of radio frames leave Antenna aperture time difference be less than the first error amount, the value of this first error amount is much smaller than the time width of time slot in radio frames, typically, this first error amount is less than the Cyclic Prefix of OFDM symbol.
Mode two: the original position of the radio frames of different radio frequency passage transmitting differs in time k time slot width when leaving Antenna aperture, k gets natural number, the span of K is 1~20, and the time slot here refers to the time slot that forms radio frames, and typical value is 0.4 millisecond.
Below the working method of above-mentioned wireless access network system is elaborated.
In the reception/transmission channel 206R/T comprising at TDD subsystem 206, reception/transmission channel 204R/T that FDD subsystem 204 comprises, transmission channel 202T that data broadcast subsystem 202 comprises, there is part radio-frequency channel can dynamically change its centre frequency and bandwidth, for example, in a radio frames, in 5 milliseconds or 10 milliseconds, radio-frequency channel can repeatedly change its center frequency point and bandwidth, and wireless access network system is included in the radio-frequency channel of working on the radio-frequency channel of exempting to work in licensed band and/or non-attribution frequency band.
Frequency spectrum in frequency spectrum corporate management unit 208 takies logging modle and takies situation, data release conditions by collecting in real time the frequency spectrum of radio-frequency channel on each frequency band, each frequency band, construct frequency spectrum and take figure, and in real time this frequency spectrum is taken to figure and upgrade, access control module takies the idle condition of each frequency band embodying on figure according to frequency spectrum, for terminal is specified the frequency band accessing, multiband scheduler module takies free time amount and the idle frequency spectrum position of each frequency band of figure embodiment according to frequency spectrum, to terminal, send to dispatch command.
In addition, the different frequency bands that above-mentioned access control module is used wireless access network system falls to sort and processes, a kind of implementation method that should fall to sort is: the frequency band that system is used sorts according to centre frequency order from low to high, band system band is divided into a plurality of sub-bands, and be numbered for every sub-frequency bands, give a natural number from small to large as this frequency band numbering of order use on time slot arranges, access control module is arranging terminal to certain frequency band, it can be the frequency band on paired frequency spectrum, also the frequency band on can the paired frequency spectrum of right and wrong, on the Time Slot Occupancy of radio frames time, in radio frames on the frequency band of odd-numbered, according to time-gap number sequence arrangement Traffic Channel from small to large, in radio frames on the frequency band of even-numbered, according to time-gap number sequence arrangement Traffic Channel from big to small.
The transmission channel 204T that frequency spectrum corporate management unit 208 can comprise FDD subsystem 204, centre frequency and the bandwidth of operation of the transmission channel 202T that data broadcast subsystem 202 comprises are controlled, to realize two dynamic frequency spectrum deployment between subsystem, generally, at digital broadcasting service in the less time period, the transmission channel 204T that the frequency spectrum 303 that data broadcast subsystem 202 is used is dynamically distributed to FDD subsystem 204 was used, to improve the transmission channel 204T of FDD subsystem 204, support the ability of downlink business, particularly, as shown in Figure 3 a, can be by adjusting the ratio between the downlink bandwidth of FDD subsystem 204 and the bandwidth of the MBMS subsystem 202 of employing private downlink carrier, centre frequency and bandwidth of operation to the MBMS subsystem 202 of FDD subsystem 204 and private downlink carrier are controlled, for example, the time period declining in broadcast traffic, by the position of separation 2 to frequency band 303 1 side shiftings, the time period of rising in broadcast traffic by the position of separation 1 to frequency band 302 1 side shiftings, the partial frequency spectrum of the frequency band of dynamically using 303 is returned to data broadcast subsystem 202 to be used.
Between the frequency band 301 that the frequency band 302 that 208 pairs of frequency spectrum corporate management unit FDD subsystem 204 is used, TDD subsystem 206 are used, carry out multiband scheduling, under the prerequisite of permission to use mode that does not change frequency band 302 and frequency band 301, allow the dynamically Traffic Channel on service band 302 and frequency band 301 of terminal.This multiband scheduling controlling of 202 pairs of terminals of data broadcast subsystem has two kinds of implementations: the frequency band 302 by FDD subsystem 204 issues dispatch command; Frequency band 301 by TDD system issues dispatch command.
Device embodiment
According to the embodiment of the present invention, provide a kind of terminal.
Fig. 6 is the terminal structure block diagram according to the embodiment of the present invention, as shown in Figure 6, according to the terminal of the embodiment of the present invention, comprise the first receive path 602, the second receive path 604, transmission channel 606, wherein, this terminal also comprises channel capacity reporting module 608 and passage control module 610.
Channel capacity reporting module 608 is for the channel parameters to network side reporting terminal by transmission channel, wherein, channel parameters can comprise following one of at least: the covering power of each passage of the receive path number of terminal, the transmission channel number of terminal, terminal, wherein, covering power comprise following one of at least: the position of the centre frequency of passage, the scheduling bandwidth of passage.
Wherein, the integrated mode of above-mentioned terminal radio frequency passage can comprise one of following:
The first radio-frequency channel integrated mode, for the first receive path 602 and the second receive path 604 are set to respectively work in the downstream bands of TDD system and the downstream bands of FDD system, and transmission channel 606 is set to work in the upstream band of FDD system or the upstream band of TDD.
The second radio-frequency channel integrated mode, for the first receive path 602 and the second receive path 604 are set to, with identical centre frequency and bandwidth, on the downstream bands of TDD system or the downstream bands of FDD system or the frequency band of digit broadcasting system, work simultaneously, or the first receive path 602 and the second receive path 604 are set to switch synchronizeing between the downstream bands of TDD system and the downstream bands of FDD system or the frequency band of digit broadcasting system.
The 3rd radio frequency combination of channels pattern; for the first receive path 602 and/or the second receive path 604 are set to carry out saltus step between its ownership frequency band and non-attribution frequency band; and transmission channel 606 is configured such that with ownership frequency band or non-attribution frequency band and receives and/or send data; wherein, belong to the frequency band on the non-paired frequency spectrum that frequency band and non-attribution frequency band are two existence protection intervals.
Further, passage control module 610 can comprise five passages control submodules, these five passages is controlled to submodules below and describes.
First passage is controlled submodule, for one of them of the first receive path 602 and the second receive path 604, be set to work in the downstream bands of FDD system, another works on the frequency band of digit broadcasting system, and transmission channel 606 is set to work in the upstream band of FDD system.
Second channel is controlled submodule, for one of them of the first receive path 602 and the second receive path 604, be set to work on the frequency band of digit broadcasting system, another works on the frequency band of TDD system, and transmission channel 606 is set to work in the upstream band of TDD system.
Third channel is controlled submodule, for the first receive path 602 and the second receive path 604 are set to respectively work in the frequency band of TDD system and the downstream bands of FDD system, and transmission channel 606 is set to work on the upstream band of FDD system or the frequency band of TDD.
Four-way is controlled submodule, for the first receive path 602 and the second receive path 604 are set to, with identical centre frequency and bandwidth, on the frequency band of TDD system or the downstream bands of FDD system or the frequency band of digit broadcasting system, work simultaneously, and/or the first receive path 602 and the second receive path 604 are set to synchronously switch between the frequency band of TDD system or the downstream bands of FDD system or the frequency band of digit broadcasting system.
Five-channel is controlled submodule; for the first receive path 602 and/or the second receive path 604 are set to carry out saltus step between its ownership frequency band and non-attribution frequency band; and transmission channel 606 is configured such that with ownership frequency band and/or non-attribution frequency band and receives and/or send data; wherein, belong to the frequency band on the non-paired frequency spectrum that frequency band and non-attribution frequency band are two existence protection intervals.
The first receive path 602 of terminal and/or the second receive path 604, under the control of channel control unit, receive and launch from transmission channel 606 mode with half-duplex or full duplex on different frequency bands.
Embodiment of the method one
According to embodiments of the invention, a kind of data transmission method is provided, for terminal, using transmission or reception data on frequency band, it is characterized in that: at least one receive path of terminal receives cell synchronous signal, scheduling controlling order on the ownership frequency band of terminal; The transmission channel of terminal sends service signal and channel detection signal using on frequency band.
The data transmission method providing by the embodiment of the present invention, the in the situation that of the quantity of same terminal radio-frequency channel, can significantly improve frequency spectrum service efficiency.
Wherein, ownership frequency band and the frequency band of using on the non-paired frequency spectrum that frequency band is two existence protection intervals, wherein, the up/down row time slot in the radio frames on ownership frequency band exists overlapping with the lower/upper row time slot of using in the radio frames on frequency band on time of occurrence.
Particularly, the uplink/downlink time slot of ownership on frequency band with use on a frequency band descending/on time of occurrence, there is overlapping comprising in ascending time slot: at ownership frequency band with use in the time interval that the ascending time slot of the radio frames on a frequency band in frequency band occurs, on another frequency band, have at least a descending time slot to occur; Or, in the time interval occurring at ownership frequency band and the descending time slot of using the radio frames on a frequency band in frequency band, on another frequency band, have at least an ascending time slot to occur.
Preferably, the signal reception of at least one receive path of terminal on the ownership frequency band of terminal carried out in the mode of half-duplex or full duplex with the signal transmitting that the transmission channel of terminal is being used on frequency band.
In addition, in the descending time slot reception control signal of at least one receive path of terminal on the ownership frequency band of terminal, the transmission channel of terminal is at the ascending time slot transmitting channel detectable signal of using on frequency band.
Embodiment of the method two
According to embodiments of the invention, a kind of data transmission method is also provided, for first terminal and the second terminal at non-attribution frequency band or use and carry out direct communication on frequency band, wherein, first terminal and described the second terminal are by synchronizeing between the WAP (wireless access point) in its ownership frequency band and the Serving cell of this terminal, realize described first terminal and participate in keeping synchronizeing between the second terminal of communication, wherein, first terminal and the second terminal receive the control signal from Serving cell WAP (wireless access point) on its ownership frequency band, and at its non-attribution frequency band or use and launch channel detection signal on frequency band.
The data transmission method providing by the embodiment of the present invention, the in the situation that of the quantity of same terminal radio-frequency channel, can significantly improve frequency spectrum service efficiency.
Can to the data transmission method of the embodiment of the present invention, describe with reference to the terminal shown in Fig. 6 below.
Particularly, first terminal and the second terminal are at its non-attribution frequency band or use the operation of launching channel detection signal on frequency band and be specially: the transmission channel of first terminal/the second terminal is transmitting channel detectable signal on the frequency band that the receive path of the second terminal/first terminal of direct communication covers with it.
Particularly, first terminal and the second terminal all receive cell synchronous signal on same ownership frequency band, and first terminal and the second terminal all realize the synchronous of two terminal rooms by synchronizeing of the synchronizing signal with on its ownership frequency band.
The operation of upper transmitting channel detection signal is specially: the transmission channel of first terminal is at the non-attribution frequency band of this terminal or use transmitting channel detectable signal on frequency band.
Wherein, on the frequency band of stipulating in the multiband scheduling controlling order that first terminal issues on its ownership frequency band and official hour, send business datum and/or channel detection signal, on the frequency band that the receive path of the second terminal is used at the transmission channel with first terminal and time slot, receive business datum and/or channel detection signal that first terminal sends.
In implementation process, can utilize the reporting module of channel capacity shown in Fig. 6 608 to pass through the transmission channel 606 of terminal to the radio-frequency channel parameter of network side reporting terminal, and utilize passage control module 610 according to the mode of operation of terminal, to come centre frequency, the bandwidth of the radio-frequency channel of configurating terminal.The mode of operation of terminal by network side according to its can with resource situation and the business of terminal request configure, and mode of operation information exchange terminal being needed by network side is crossed air interface and is handed down to terminal.
Wherein, the first receive path 602, the second receive paths 604 of terminal, transmission channel 606, under the control of passage control module 610, repeatedly changes its centre frequency and bandwidth in a radio frames, to realize the multiband scheduling to terminal.
Below five of terminal kinds of modes are elaborated.
Mode one: terminal is carried out Digital Broadcasting Receiver and communicating by letter with FDD mode and network simultaneously.Under this mode of operation, the first receive path 602 of terminal or the second receive path 604 work in the downstream bands 302 of FDD, simultaneously, the second receive path 604 or the first receive path 602 work on digital broadcasting frequency band 303, transmission channel 606 is operated in the uplink spectrum of FDD, is operated on frequency band 304.Owing to being operated between the first receive path 602 on digital broadcasting frequency band or the second receive path 604 and transmission channel 606, exist isolate bands, can between passage, not produce serious transmitting-receiving and disturb.This mode also can realize terminal and with FDD mode and network, carry out single-point communicating by letter to single-point when digital broadcasting frequency band receives downloading data.
Mode two: terminal is carried out Digital Broadcasting Receiver and communicating by letter with TDD mode and network simultaneously, under this mode of operation, the first receive path 602 or second receive path 604 of terminal work on digital broadcasting frequency band 303, simultaneously, the second receive path or the first receive path work on TDD frequency band 301, transmission channel 606 is operated in the uplink spectrum of TDD, owing to being operated between the first receive path 602 on digital broadcasting frequency band or the second receive path 604 and transmission channel 606, exist frequency band 302 as isolate bands, can between passage, not produce serious transmitting-receiving disturbs, this mode also can realize terminal and with TDD mode and network, carry out single-point communicating by letter to single-point when digital broadcasting frequency band receives downloading data.
Mode three: terminal receives data from network simultaneously on two non-conterminous frequency bands, concrete grammar is: terminal is used the second receive path 604 and the first receive path 602 to work in respectively in TDD frequency band 301 and FDD downstream bands 302 simultaneously, from these two frequency bands, obtain the data that network issues, further, terminal is used transmission channel 606 on frequency band 304, or to network, sends data on frequency band 304.
Mode four: multiband scheduling in heterogeneous radio access networks.The first receive path 602 of terminal is operated on frequency band 302 or frequency band 303 or frequency band 301 with identical centre frequency and bandwidth with the second receive path 604 simultaneously.And, the first receive path 602 and the second receive path 604 synchronously switch between frequency band 302, frequency band 303, frequency band 301, realization is space diversity or the spatial reuse on frequency band 302, frequency band 303, frequency band 301 in the mode of time-division, receives the spectrum efficiency of signal to improve terminal.When carrying out multiband scheduling, the first receive path 602 and/or the second receive path 604 turn back to periodically on its ownership frequency band and receive and control data or Cell Broadcast CB data.
Mode five: the multiband scheduling between heterogeneous radio access networks and other system.Between frequency band outside the frequency band that the centre frequency of (1) first receive path 602 and/or the second receive path 604 has at the heterogeneous radio access networks shown in its ownership frequency band and Fig. 3, carry out saltus step, use the frequency band of using to receive data; Between frequency band outside the frequency band that the centre frequency of (2) first receive paths 602 and/or the second receive path 604 has at the heterogeneous radio access networks shown in its ownership frequency band and Fig. 3, carry out saltus step, and transmission channel 606 uses the frequency band of using to send data, on non-attribution frequency band, realize the communication of terminal to terminal.
Wherein, radio-frequency channel reporting parameters module 608 reports its channel capacity to network side, comprises one or more of following data: the receive path number that can work alone, passage number that can independent transmission, the covering power of each passage; The covering power of passage further comprises: the position of the centre frequency of passage, the adjustable-width of passage.
Embodiment of the method three
According to embodiments of the invention, provide a kind of method of dispatch terminal, for dispatch terminal between different frequency bands.
According to the method for the dispatch terminal of the embodiment of the present invention, comprise: network side is distributed to serially in time same terminal by the frequency spectrum resource on the first frequency band and the second frequency band and used; In very first time interval, network side is the resource on terminal distribution the first frequency band; In the second time interval, network side is the resource on terminal distribution the second frequency band; Wherein, within very first time interval and the second time interval are included in the duration of a wireless frame period.
The method of the dispatch terminal providing by the embodiment of the present invention, can effectively utilize the free timeslot on different frequency bands, can significantly improve frequency spectrum service efficiency.
Wherein, between the first frequency band and the second frequency band, have interval, and the first frequency band and the second frequency band comprise one of following: two frequency bands that have the TDD system at interval; Two upstream or downstream frequency bands that have the FDD system at interval; The frequency band of two up or downstream bands by FDD system and the TDD system that is adjacent merges the frequency band forming; One is that the up or downstream bands of FDD system and the frequency band of the TDD system being adjacent merge the frequency band forming, and one is the frequency band of TDD system.
Wherein, network side is that the operation of the resource on terminal distribution the first frequency band or the second frequency band is specially: network side is the idle frequency spectrum resource on terminal distribution the first frequency band and the second frequency band.
Wherein, network side is that the operation of the idle frequency spectrum resource on terminal distribution the first frequency band and the second frequency band comprises one of following: in very first time interval, part or all of downlink or uplink idle frequency spectrum in the frequency band of the TDD system as the first frequency band is distributed to terminal to be used, in the second time interval thereafter, the part or all of downlink or uplink idle frequency spectrum in the another one frequency band of the TDD system as the second frequency band is distributed to terminal and use; Or, in very first time interval, part or all of downlink or uplink idle frequency spectrum in the frequency band of the TDD system as the first frequency band is distributed to terminal to be used, in the second time interval thereafter, the part or all of downlink or uplink idle frequency spectrum in the frequency band of the FDD system as the second frequency band is distributed to terminal and use; Or, in very first time interval, part or all of downlink or uplink idle frequency spectrum in the frequency band of the TDD system as the first frequency band is distributed to terminal to be used, in the second time interval thereafter, using the frequency band of the FDD system as the second frequency band and with it the part or all of downlink or uplink idle frequency spectrum in adjacent TDD band system band distribute to terminal and use.
In addition, wireless access network sends scheduling of resource instruction by the ownership frequency band of terminal to terminal, and wherein, scheduling of resource instruction is designated as the width information of frequency spectrum and the time slot position information of frequency spectrum of terminal distribution.
Preferably, the duration of a wireless frame period is the integral multiple of 5 milliseconds or 5 milliseconds.
According to the method for dispatch terminal between a plurality of frequency bands of the embodiment of the present invention, be applicable to have the wireless access network of a plurality of radio-frequency channels and a plurality of frequency bands and the communication system that multichannel terminal forms.The multiband dispatching method that the embodiment of the present invention provides, both be applicable to the system that the mode with shown in Fig. 3 that multichannel terminal that heterogeneous radio access networks that Fig. 2 provides and Fig. 4 provide forms configures its radio-frequency channel, be also applicable to the scheduling to terminal on a plurality of discrete non-paired frequency bands of the multichannel terminal formation shown in the heterogeneous radio access networks shown in Fig. 2 and Fig. 6.
In the process of accessing terminal to network or after accessing terminal to network, one of the terminal assignments that the access control module of network side is request access belongs to frequency band or is referred to as resident frequency band, this ownership frequency band can be the non-paired frequency band that a TDD system is used, also can be the paired frequency band that FDD system is used, network side provides as lower channel to terminal by the ownership frequency band of terminal: CBCH, uplink synchronous channel, scheduling controlling channel between descending synchronous signal channel and frequency band, on other non-attribution frequency band (or being referred to as non-attribution frequency band), only to the terminal being scheduled, provide Traffic Channel, measure channel.The non-attribution frequency band being scheduled to the actual use of terminal is referred to as target band, and target band also comprises the ownership frequency band of terminal.
Wherein, target band can be a frequency band, can be also a plurality of frequency bands that used successively in time.Particularly, target band can be one or more combination of following frequency band: the downlink dedicated carrier wave place frequency band that the frequency band of the non-paired frequency spectrum that the frequency band in the paired frequency spectrum that FDD system is used, TDD system are used, media multicast and broadcast are used, exempt from frequency band in licensed band, license to the idle frequency band in the frequency spectrum of ground TV broadcast system.
The composition of terminal 503a/503b shown in Fig. 5 as shown in Figure 7, first terminal 503a and the second terminal 503b comprise respectively: 702, one the second receive paths 703 of 701, one the first receive paths of a baseband processing unit, 704, one antenna elements 707 of a transmission channel.A baseband processing unit 701 comprises that 704, one channel capacities of a channel control unit report unit 705.
Below with reference to Fig. 3, Fig. 5 and Fig. 7, the another kind of implementation method that first terminal 503a is directly sent to high data rate to the second terminal 503b is described in detail.
(1) in very first time interval, to the second terminal 503b, the frequency band 301 on radio node 502b was last has completed Cell searching and synchronous for first terminal 503a, and the access control module in frequency spectrum corporate management unit 208 is by the 301 ownership frequency bands of being appointed as these two terminals.The reporting parameters unit, radio-frequency channel 706 of first terminal 503a and the second terminal 503b has reported its radio-frequency channel parameter to network respectively, comprise: its transmission channel 704 has the ability that covers frequency band 301,304 and ground digital television broadcast frequency range 470MHz~698MHz, two receive path 702,703 has the ability that covers frequency band 301,302,303 and ground digital television broadcast frequency range 470MHz~698MHz.
(2) in the second time interval, the transmitting on its ownership frequency band 301 of the transmission channel 704 of first terminal 503a directly sends the request signal of business datum to the second terminal 503b, or the transmitting on its ownership frequency band 301 of the transmission channel 704 of the second terminal 503b directly receives the request signal of business datum from first terminal 503a.
(3), in the 3rd time interval, TDD subsystem sends frequency band scheduling instruction to first terminal and the second terminal on its ownership frequency band 301, indicates following parameter: 1) terminal is by the frequency band B_sch using and the position of time slot thereof to terminal; 2) on the assigned timeslot TS_T in the radio frames of the transmission channel 704 of controlling first terminal on B_sch, launch, control the second terminal receive path 702 and or 703 on identical time slot TS_T, receive; And, control first terminal receive path 702 and or 703 radio frames on B_sch on assigned timeslot TS_R on receive, on same assigned timeslot TS_R in the same radio frames of the transmission channel 704 of controlling the second terminal on B_sch, launch, to realize shaking hands in transmission, control and autonomous retransmission.The access band information that the channel control unit 705 of terminal issues according to network, is configured to the transmission channel of terminal and receive path on frequency band B_sch.
(4) in the 4th time interval, first terminal and the second terminal are sent and receive indication information to TDD subsystem respectively, and TDD subsystem is cancelled the time slot of distributing to these two terminals at B_sch.
In the present embodiment, frequency band B_sch is a frequency band of using from digital television broadcasting frequency range 470MHz~698MHz.Frequency band B_sch can be also the licensed band of TDD system, can be also the frequency band of exempting from licensed band.
Fig. 8 shows the instantiation schematic diagram according to the method for the dispatch terminal of the embodiment of the present invention, as shown in Figure 8, can this embodiment be described with reference to wireless access network shown in Fig. 2, specifically comprises the following steps:
Step S802, one group of candidate band is determined for multiband scheduling in frequency spectrum corporate management unit 208, specifically by following three steps, implements.
The first step, one group of potential frequency band is determined for terminal in frequency spectrum corporate management unit 208.
Particularly, frequency spectrum corporate management unit 208 is from M the frequency band that ownership radio-frequency channel place radio node and the relevant radio node thereof of terminal has, choosing can be by the frequency band of N available free time slot of terminal-receiving passage or transmission channel covering as channel measurement frequency band, wherein, above-mentioned relevant radio node can be one of following radio node: the radio node of the community adjacent with community, terminal place, or, under layered network architecture, cover the radio node of other one deck of community, terminal place; Further, in order to reduce the surveying work amount of terminal, in a plurality of frequency bands of a shared same antenna, only choose one of them and carry out channel measurement.
Second step, terminal mode with appointment on the potential frequency band of frequency spectrum corporate management unit 208 appointments is carried out channel measurement, below the specific implementation process of this step is described in detail.
First, the ownership passage of frequency spectrum corporate management unit 208 by terminal sends potential frequency band carried out to the instruction of channel measurement to terminal on the ownership frequency band of terminal, and this channel measurement instruction comprises: the numbering of frequency band to be measured, use place, the radio-frequency channel radio node of frequency band to be measured or the numbering of antenna used, terminal on potential frequency band, to carry out the mode of channel measurement; Then, terminal is measured and calculating path loss parameter potential frequency band according to the frequency band of network appointment and metering system.
Wherein, the mode that terminal is carried out channel measurement on potential frequency band has following two kinds:
(1) terminal sends predetermined channel detection signal to network on frequency band to be measured, one or more radio node of network side receive channel detectable signal calculate the path loss between terminal and radio node on this frequency band on corresponding frequency band.
(2) terminal receives from the known measuring-signal of the form of one or more radio node on frequency band to be measured, and calculates the path loss between terminal and radio node on this frequency band, and measurement result is reported to frequency spectrum corporate management unit 208.
The method of above-mentioned terminal transmitting channel detectable signal on potential frequency band is: a transmission channel of terminal is used on the frequency band that two antennas of terminal are identical to network transmitting channel detectable signal in the mode of time-division, and one or more radio node of network side channel detection signal that synchronously receiving terminal sends computing terminal are to channel impulse response data and the path loss of above-mentioned radio node; When radio node comprises a plurality of reception antenna, path loss is that each transmitting antenna of terminal is to the mean value of one group of path loss of one group of reception antenna.
The method of above-mentioned terminal receive channel detectable signal on potential frequency band is: two transmission channels of terminal receive the known measuring-signal of form that radio node sends simultaneously and calculate the channel impulse response of every group of dual-mode antenna; When radio node comprises a plurality of transmitting antenna, path loss is each reception antenna of terminal and the mean value of the path loss between the transmitting antenna on one group of radio node, and terminal reports network by its ownership frequency band by the measured value of path loss.
The 3rd step, the candidate band of one group of multiband scheduling is determined in frequency spectrum corporate management unit 208 to the measurement result of potential frequency band according to terminal.
Particularly, frequency spectrum corporate management unit 208 compares terminal on potential frequency band with the path loss of different radio node and the thresholding TH_los of reservation, and a surviving path loss is less than the potential frequency band on the radio node of subscribing thresholding TH_los; The potential frequency band that frequency spectrum corporate management unit 208 is less than the path loss remaining on the radio node of subscribing thresholding TH_los sorts according to the size of its path loss, when two or more candidate band are while belonging to the same frequency band of different radio node, corresponding that candidate band of radio node that only retains a path loss minimum, consequently, in the candidate band of selecting, there is not the frequency band repeating.
Step S804, target band and mode of operation thereof are determined in frequency spectrum corporate management unit 208 from candidate band, particularly, can implement by following three steps.
The first step, frequency spectrum corporate management unit 208 takies from frequency spectrum the idle frequency spectrum resource data that logging modle is obtained each candidate band, and make the following judgment: judge whether the needed frequency spectrum resource of business that exists its idle frequency spectrum resource of a frequency band can meet terminal request, judgment result is that be in the situation that, proceed to second step; In the situation that the determination result is NO, further judge whether to exist two or more its free timeslots to have in time staggered frequency band, and exist frequency spectrum resource on the staggered free timeslot in time with different frequency bands to be connected in series successively the needed frequency spectrum resource of business that can meet terminal request after use these, in the situation that further judgment result is that of judgement is, proceed to the 3rd step, in the situation that further judge that the determination result is NO, stop the credit rating to the business of the multiband scheduling of terminal or reduction terminal request.
Second step, the target band that frequency spectrum corporate management unit 208 is dispatched an above-mentioned single frequency band as multiband.
The 3rd step, the target band of frequency spectrum corporate management unit 208 scheduling using two or frequency band as multiband, and determine an order of using successively the free timeslot in these target band for terminal.
Step S806, frequency spectrum corporate management unit 208 sends multiband dispatch command by ownership frequency band to terminal.
Wherein, the multiband dispatch command sending comprises following content: the numbering of the numbering of definite target band, target band place WAP (wireless access point) and the occupation mode of terminal to target band in step S804, and terminal comprises one of following mode to the occupation mode of target band: terminal is used a target band to transmit data, terminal is used successively two or more target band to transmit serially data in a radio frames.
Further, dispatch command is the position of terminal assignments running time-frequency resource of transmitting channel detectable signal in target band; The result of network based channel detection, transmits the wireless link form of data between the terminal of working in target band for terminal assignments further and network, above-mentioned wireless link form is one of following: space diversity, spatial reuse.
After terminal is received above-mentioned dispatch command, the mode indicating according to dispatching command, terminal communicates with network in target band, or terminal communicates with another one terminal in target band.
Below in conjunction with the method shown in Fig. 8, to terminal being carried out to multiband scheduling in downlink transfer, be elaborated, and with reference to Fig. 2, Fig. 5 and Fig. 6, this example is described, wherein, can form an isomery multiband distributed communication system according to the multichannel terminal shown in the heterogeneous radio access networks shown in Fig. 2, Fig. 6 and the networking mode shown in Fig. 5.
Below with reference to the networking mode shown in Fig. 5, be given in the specific implementation method of dispatch terminal 503a between different frequency bands.Before multiband scheduler module in the joint spectrum administrative unit of network side is carried out multiband scheduling to terminal 503a, the frequency band 302 of terminal 503a on radio node 501 be last has completed Cell searching and synchronous, and the access control module in frequency spectrum corporate management unit 208 is by the 302 ownership frequency bands of being appointed as this terminal.The radio-frequency channel reporting parameters module 608 of terminal 503a reports its radio-frequency channel parameter to network side respectively, this radio-frequency channel parameter specifically comprises: the transmission channel 606 of terminal has the ability that covers frequency band 301,304, and two receive path 602,604 has the ability that covers frequency band 301, frequency band 302, frequency band 303.
First, one group of candidate band is determined for multiband scheduling in frequency spectrum corporate management unit 208, is divided into three steps below and carries out this process to be described in detail.
The first step, 3 of having from place, the ownership radio-frequency channel radio node 502b of terminal 503a and relevant radio node 502a, radio node 502c and radio node 501 in frequency spectrum corporate management unit 208 can be used for the frequency band 301,302,303 of downlink transfer, choose the frequency band 301,302,303 of 3 available free time slots that can be covered by terminal-receiving passage or transmission channel as channel measurement frequency band.
Second step, terminal is carried out channel measurement in the mode of appointment on the potential frequency band 301,302,303 of frequency spectrum corporate management unit 208 appointments.
Particularly, frequency spectrum corporate management unit 208 is sent potential frequency band is carried out to the instruction of channel measurement to terminal on the ownership frequency band of terminal by the ownership passage of terminal, channel measurement instruction comprises: frequency band 301 to be measured, 302, 303 numbering, use place, the radio-frequency channel radio node 501a of frequency band to be measured, 502b, 502c and 501 numbering, and designated terminal is at frequency band 301 to be measured, 302, on 303, receive from radio node 501a, 502b, 502c and 501 measuring-signal, and calculate on this frequency band channel impulse response and the path loss between every pair of dual-mode antenna between terminal and radio node, and measurement result is reported to frequency spectrum corporate management unit 208, particularly, terminal is to from radio node 501a, 502b, the measuring-signal of 502c and 501 FDD down going channel is reference signal (the Reference Signal Received Power switching for community, referred to as RSRP), terminal is reference signal or the antenna identification signal of the transmitting of MBMS system to the measuring-signal of the frequency band 303 on 501.
The 3rd step, the candidate band of one group of multiband scheduling is determined in frequency spectrum corporate management unit 208 to the measurement result of potential frequency band according to terminal.
Particularly, frequency spectrum corporate management unit 208 compares terminal on potential frequency band 301,302,303 with the path loss of different radio node and the thresholding TH_los of reservation, surviving path loss is less than the potential frequency band on the radio node of subscribing thresholding TH_los, and the result obtaining is: only have the frequency band on radio node 502b and radio node 501 to be retained, after this, the potential frequency band that frequency spectrum corporate management unit 208 is less than the path loss remaining on the radio node of subscribing thresholding TH_los sorts according to the size of its path loss, according to terminal, to the ranking results of the path loss of radio node, see Fig. 8, from first its path loss of frequency band to the three frequency bands, increase successively, the reason that causes path loss between radio node 501 and terminal to be less than radio node 502b is that the decorating position that radio node 501 is high makes the propagation path having had between radio node 501 and terminal, so 301, 302, 303 as candidate band.
Secondly, target band and mode of operation thereof are determined in frequency spectrum corporate management unit 208 from candidate band, be divided into two steps below this process is described in detail.
The first step, frequency spectrum corporate management unit 208 takies the idle record of logging modle to the different frequency bands on each radio node according to frequency spectrum, obtains the current idle data of frequency band 301,302,303, sees Fig. 9 (a).Then, judge the spectrum requirement that whether has a frequency spectrum resource on its free timeslot of frequency band can meet the business that terminal asks in frequency band 301,302,303, if judged result is the frequency spectrum resource on the free timeslot on frequency band 301, can meet the demands, proceed to second step.
In above-mentioned scheduling process, if to whether exist its idle frequency spectrum resource of a frequency band can meet terminal request the needed frequency spectrum resource of business judged result whether, frequency spectrum corporate management unit 208 is further done as judged: in candidate band 301, 302, in 303, whether exist two its free timeslots to have in time staggered frequency band, and exist frequency spectrum resource on the staggered free timeslot in time with different frequency bands to be connected in series successively the needed frequency spectrum resource of business that can meet terminal request after use these, judged result is, see Fig. 9 (b): by the idle frequency band in frequency band 301 descending time slots 1., 2. free timeslot in frequency band 302 passes and connects the needed frequency spectrum resource of business that use can meet terminal request.
Second step, the target band that frequency spectrum corporate management unit 208 is dispatched above-mentioned frequency band 301 as multiband, and by the frequency spectrum resource on frequency band 301 free timeslots 1. assignment to terminal, use.
Finally, frequency spectrum corporate management unit 208 sends multiband dispatch command by ownership frequency band to terminal; Wherein, the multiband dispatch command of transmission comprises one of at least following content: the position indication 1. of the numbering of the numbering of the determined target band 301 of step S804, target band 301 place WAP (wireless access point) 502b, the frequency spectrum resource on frequency band 301 free timeslots and the running time-frequency resource position of terminal 503a transmitting channel detectable signal in target band 301.
In addition, frequency spectrum corporate management unit 208 sends multiband dispatch command by ownership frequency band to terminal, and the multiband dispatch command of transmission comprises following content: numbering and the serial occupation mode of terminal 503a to target band 301 and 302 of above-mentioned definite target band 301 and 302 numbering, target band 301 and 302 place WAP (wireless access point) 502b and 501.Terminal 503a to the serial occupation mode of target band 301 and 302 is: the receive path of terminal 402 and receive logical 403 and first receive data at the free timeslots of frequency band 301 on 1., then jumps to the 2. upper data that receive of free timeslot in frequency band 302.
In the present embodiment, network side, according to the measurement of the channel detection signal that terminal is launched in target band 301, determines that the mode that 1. free timeslot of terminal on frequency band 301 gone up with double-current spatial reuse receives the data that network sends, and sees Fig. 9 (a).
Further, for raising system has the service efficiency of frequency band, the different frequency bands that the access control module in frequency spectrum corporate management unit 208 is used system falls sequence processing, sees Figure 10.If be not exist its free timeslot and bandwidth to meet the frequency band of terminal traffic demand to the judged result of candidate band 301,302,303, even if use and also cannot meet the needs of terminal by two frequency bands serial connection 1. and 2..Appearance for fear of this situation, the different frequency bands that access control module in frequency spectrum corporate management unit 208 is used system falls to sort and processes, a kind of implementation method of falling to sort is: the business in frequency band 301 descending time slots is started to the prime direction arrangement to radio frames from up-downgoing transfer point, allow free timeslot 1. concentrate and to appear at descending time slot original position one side.By the free timeslot on frequency band 301, be 1. 2. connected in series use with the free timeslot in frequency band 302, can maximally utilise a free timeslot in radio frames, see Figure 10.
Below in conjunction with the method shown in Fig. 8, to being elaborated of dispatch terminal between two non-paired frequency bands, and with reference to Fig. 2, Fig. 5, Fig. 6 and Figure 11, this example is described, wherein, can form an isomery multiband distributed communication system according to the multichannel terminal shown in the heterogeneous radio access networks shown in Fig. 2, Fig. 6 and the networking mode shown in Fig. 5.
Structure to this isomery multiband distributed communication system describes, as shown in figure 11, the radio-frequency channel of TDD system is included in two radio-frequency channels of a TDD frequency band 301a and the upper work of the 2nd TDD frequency band 301b, and, in the networking mode shown in Fig. 5, two radio-frequency channels that are operated on a TDD frequency band 301a and the 2nd TDD frequency band 301b of TDD system belong to same radio node (or same RRU) 502b, or use same set of antenna or use to be arranged on the different antennae on same site.In the present embodiment; in TDD licensed band, there is a frequency band at protection interval with frequency band 301a in the 2nd TDD frequency band 301b; in the present embodiment; the 2nd TDD frequency band 301b is a frequency band that belongs to licensed band 1900MHz~1920MHz of TDD, and the 2nd TDD frequency band 301b can be also from the idle frequency band of ground TV broadcast frequency range 470MHz~698MHz or the frequency band of exempting to borrow licensed band.
Before multiband scheduler module in the joint spectrum administrative unit 208 of the network side shown in Fig. 2 b is carried out multiband scheduling to terminal 503a, the frequency band 301a of terminal 503a on radio node 502b was last has completed Cell searching and synchronous, and the access control module in frequency spectrum corporate management unit 208 is appointed as 301a on the ownership frequency band of this terminal.The reporting parameters unit, radio-frequency channel 610 of terminal 503a has reported its radio-frequency channel parameter to network side respectively, this radio-frequency channel parameter comprises: the transmission channel 606 of terminal has the frequency band of covering 301a, frequency band 301b, the ability of frequency band 304 and ground digital television broadcast frequency range 470MHz~698MHz, and two receive paths 602 of terminal, 604 have the frequency band of covering 301a, frequency band 301b, frequency band 302, the ability of frequency band 303 and ground digital television broadcast frequency range 470MHz~698MHz, wherein, frequency band 4/ frequency band 1101 shown in Figure 11 is exactly a frequency band that belongs to 470MHz~698MHz.
When terminal has initiated to network uplink service request that transmission rate is 200Mbps, first, frequency spectrum corporate management unit 208 is that one group of candidate band is determined in multiband scheduling, and this process is described in detail in two steps below.
The first step, frequency band 301a, the frequency band 301b that frequency spectrum corporate management unit 208 has from place, the ownership radio-frequency channel radio node 502b of terminal 503a and relevant radio node 502a, radio node 502c and radio node 501, frequency band 302, choose frequency band 301a, the frequency band 301b of the available free time slot that can be covered by terminal-receiving passage or transmission channel as channel measurement frequency band.
Second step, terminal is carried out channel measurement in the mode of appointment on potential frequency band 301a, the frequency band 301b of frequency spectrum corporate management unit 208 appointments.
Particularly, frequency spectrum corporate management unit 208 is sent potential frequency band is carried out to the instruction of channel measurement to terminal on the ownership frequency band of terminal by the ownership passage of terminal, channel measurement instruction comprises: frequency band 301a to be measured, the numbering of frequency band 301b, use place, the radio-frequency channel radio node 502a of frequency band to be measured, 502b, the numbering of 502c, and designated terminal is at frequency band 301a to be measured, the upper transmitting channel detectable signal of frequency band 301b, the radio node radio node 502a of network side, 502b, the channel detection signal that 502c receiving terminal 503a sends also calculates on this frequency band channel impulse response and the path loss between every pair of dual-mode antenna between terminal and radio node, and measurement result is reported to frequency spectrum corporate management unit 208.
The 3rd step, the candidate band of one group of multiband scheduling is determined in frequency spectrum corporate management unit 208 to the measurement result of potential frequency band according to terminal.
Particularly, frequency spectrum corporate management unit 208 compares terminal on potential frequency band 301a, frequency band 301b with the path loss of different radio node and the thresholding TH_los of reservation, surviving path loss is less than the potential frequency band on the radio node of subscribing thresholding TH_los, and the result obtaining is: frequency band 301a, frequency band 301b on radio node 502b are retained, after this, the potential frequency band that frequency spectrum corporate management unit 208 is less than the path loss remaining on the radio node of subscribing thresholding TH_los sorts according to the size of its path loss, according to terminal, to the ranking results of the path loss of radio node, be: the path loss between terminal and radio node 502b on frequency band 301a is less than frequency band 301b, frequency band 301a and frequency band 301b belong to from same radio node, the reason that the path loss of terminal on frequency band 301a is less than the path loss of terminal on frequency band 301b is that the frequency range of frequency band 301a is lower, so frequency band 301b, frequency band 301a is as candidate band.
Secondly, target band and mode of operation thereof are determined in frequency spectrum corporate management unit 208 from candidate band, below this process are described in detail.
Frequency spectrum corporate management unit 208 takies the idle record of logging modle to the different frequency bands on each radio node according to frequency spectrum, obtains frequency band 301a and the current idle data of frequency band 301b.Then, idle frequency spectrum resource on judgement frequency band 301b or frequency band 301a can meet the needed frequency spectrum resource of business of terminal request, in the situation that the determination result is NO, frequency spectrum corporate management unit 208 is further done as judged: whether the free timeslot at candidate band 301b and frequency band 301a exists staggered in time, and these in time the frequency spectrum resource on staggered free timeslot be connected in series successively the needed frequency spectrum resource of business that can meet terminal request after use, in judged result, be in satisfiable situation, frequency spectrum corporate management unit 208 is by the idle frequency band U1 in frequency band 301a ascending time slot, frequency band U2 in up free timeslot in frequency band 301b is connected in series and uses to meet the needed frequency spectrum resource of business of terminal request.
Finally, frequency spectrum corporate management unit 208 sends multiband dispatch command by ownership frequency band to terminal, wherein, the multiband dispatch command of transmission comprises following content: the numbering of the numbering of above-mentioned definite target band 501a and frequency band 301b, target band 301a and frequency band 301b place WAP (wireless access point) 502b and the serial occupation mode of terminal 503a to target band 01a and frequency band 301b.Terminal 503a to the serial occupation mode of target band 301a and frequency band 301b is: the first receive path 602 of terminal and second receives logical 604 and first on the free time of frequency band 301a, sends upstream data 1., terminal is when transmission upstream data 1., 2. its receive path 606 carries out channel measurement to downstream signal on frequency band 301b, and, 3. measurement data is reported to network in the mode of code book at frequency band 301a, by the down channel on frequency band 301b, by terminal, 4. the mode of operation designation data on the uplink spectrum U2 on frequency band 301b is handed down to terminal to network, terminal completes after up transmitting on frequency band 301a, 5. the mode of operation of 4. indicating according to mode of operation designation data on the uplink spectrum U2 of frequency band 301b sends data to network.
As mentioned above, by means of the configuration mode of radio-frequency channel different classes of in heterogeneous radio access networks of the present invention, both solved the allocation problem of MBMS special carrier, the interference of transmission channel to MBMS receive path while also having avoided terminal receive MBMS signal simultaneously and carry out point-to-point communication, simultaneously, according to of the present invention on a plurality of frequency bands the method for dispatch terminal can effectively utilize the free timeslot on different frequency bands, improved frequency spectrum service efficiency, and, the in the situation that of the quantity of same terminal radio-frequency channel, adopt merging of the present invention to use method or the multiband dispatching method of frequency spectrum can significantly improve spectrum efficiency.
The foregoing is only the preferred embodiments of the present invention, be not limited to the present invention, for a person skilled in the art, the present invention can have various modifications and variations.Within the spirit and principles in the present invention all, any modification of doing, be equal to replacement, improvement etc., within all should being included in protection scope of the present invention.
Claims (4)
1. a method for dispatch terminal, for dispatch terminal between different frequency bands, is characterized in that, comprising:
Network side is distributed to serially in time same terminal by the frequency spectrum resource on the first frequency band and the second frequency band and is used;
In very first time interval, network side is the resource on the first frequency band described in described terminal distribution;
In the second time interval, network side is the resource on the second frequency band described in described terminal distribution;
Wherein, within described very first time interval and described the second time interval are included in the duration of a wireless frame period; Between described the first frequency band and described the second frequency band, have interval, it is one of following that described the first frequency band and described the second frequency band comprise: two frequency bands that have the TDD system at interval; Two upstream or downstream frequency bands that have the FDD system at interval; The frequency band of two up or downstream bands by FDD system and the TDD system that is adjacent merges the frequency band forming; One is that the up or downstream bands of FDD system and the frequency band of the TDD system being adjacent merge the frequency band forming, and one is the frequency band of TDD system.
2. method according to claim 1, it is characterized in that, described network side is that the operation of the resource on the first frequency band or described the second frequency band described in described terminal distribution is specially: described network side is the idle frequency spectrum resource on the first frequency band and described the second frequency band described in described terminal distribution.
3. method according to claim 2, is characterized in that, described network side is that the operation of the idle frequency spectrum resource on the first frequency band and described the second frequency band described in described terminal distribution comprises one of following:
In described very first time interval, part or all of downlink or uplink idle frequency spectrum in the frequency band of the TDD system as described the first frequency band is distributed to described terminal to be used, in described the second time interval thereafter, the part or all of downlink or uplink idle frequency spectrum in the another one frequency band of the TDD system as described the second frequency band is distributed to described terminal and use; Or
In described very first time interval, part or all of downlink or uplink idle frequency spectrum in the frequency band of the TDD system as described the first frequency band is distributed to described terminal to be used, in described the second time interval thereafter, the part or all of downlink or uplink idle frequency spectrum in the frequency band of the FDD system as described the second frequency band is distributed to described terminal and use; Or
In described very first time interval, part or all of downlink or uplink idle frequency spectrum in the frequency band of the TDD system as described the first frequency band is distributed to described terminal to be used, in described the second time interval thereafter, using the frequency band of the FDD system as described the second frequency band and with it the part or all of downlink or uplink idle frequency spectrum in adjacent TDD band system band distribute to described terminal and use.
4. method according to claim 1, is characterized in that,
Wireless access network sends scheduling of resource instruction by the ownership frequency band of described terminal to described terminal, and wherein, described scheduling of resource instruction is designated as the width information of frequency spectrum and the time slot position information of frequency spectrum of described terminal distribution.
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CN104618911B (en) * | 2013-11-05 | 2019-04-09 | 中国移动通信集团公司 | A kind of method, apparatus of communication between devices, system and relevant device |
CN105917715B (en) * | 2014-01-23 | 2019-07-23 | 华为技术有限公司 | Terminal scheduling method, website and terminal |
KR102222249B1 (en) * | 2014-09-01 | 2021-03-04 | 삼성전자주식회사 | Device Using Antenna |
US11399378B2 (en) | 2015-11-20 | 2022-07-26 | Guangdong Oppo Mobile Telecommunications Corp., Ltd. | Method and terminal for data transmission using unlicensed carrier |
CN107710822B (en) | 2015-12-15 | 2022-03-15 | Oppo广东移动通信有限公司 | Carrier hopping method, terminal and base station |
WO2019084799A1 (en) * | 2017-10-31 | 2019-05-09 | Oppo广东移动通信有限公司 | Method, terminal device, and network device for reporting frequency spectrum |
CN111225442B (en) * | 2018-11-26 | 2022-12-30 | 普天信息技术有限公司 | Measurement and data scheduling method and system |
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CN1878053A (en) * | 2005-06-07 | 2006-12-13 | 华为技术有限公司 | Multiplexing method for time-frequency resource in radio communication system |
CN1889402A (en) * | 2005-06-28 | 2007-01-03 | 华为技术有限公司 | Multiplexing realizing method for radio communication system time frequency resource |
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