CN104429144A - A resource scheduling method, an information interaction method and a device - Google Patents

Abstract

Provided are a resource scheduling method, an information interaction method and a device. A base station which a multi-stream region corresponding to a user belongs to obtains downlink data throughput rates of the user in multi-stream regions controlled by other base stations; a resource scheduling priority degree of the user in the multi-stream region controlled by the base station is determined according to the throughput rates of the user in the multi-stream regions controlled by the other base stations and the throughput rate of the user in multi-stream region controlled by the corresponding base station; according to the determined resource scheduling priority degree, the resources in the multi-stream region controlled by the corresponding base station of the user are scheduled for the user. Through adoption of the technical scheme of the invention, problems in the prior art that when base station crossing for multi-stream regions exists, the base stations can not realize equal resource scheduling.

Description

Resource regulating method, information interacting method and equipment

Technical field

The present invention relates to wireless communication technology field, particularly relate to a kind of resource regulating method, information interacting method and equipment.

Background technology

Third generation partner program (3rd Generation Partnership Project, 3GPP) in the 5th version (Release 5), introduce high-speed slender body theory (High Speed Downlink PacketAccess, HSDPA) technology, can provide high-speed down data sendaisle for user.But, user can only set up HSDPA passage with a community simultaneously, as shown in Figure 1A, and be positioned at the user of cell edge, because wireless environment is poor, even if user uses HSDPA channel reception downlink data, the downlink data throughput of this user is still far below the downlink data throughput of the user of center of housing estate.

For the problems referred to above, 3GPP introduces HSDPA multi-stream technology in the 11st version (Release 11), Cell Edge User can set up HSDPA passage with the multiple communities covering this user simultaneously, by the downlink data transmission scheduling resource that the multiple communities covering this user are this user simultaneously, add downlink data sendaisle, improve the downlink data throughput of edge customer.

When HSDPA passage is set up in user and multiple community simultaneously, each community setting up HSDPA passage with user is called the multithread community that this user is current, each multithread community in multiple multithread community composition multithread cell set multithread cell set that user is corresponding may belong to same base station, also may belong to different base stations.

As shown in Figure 2 A, when the multithread community that user is corresponding belongs to same base station, can be the resource of each multithread community of downlink data transmission United Dispatching of user by this base station, each multithread community justice shares load corresponding to this user, makes local resource obtain maximum using.In addition, the wireless quality that each community arrives user is fluctuation, in each multithread community of multithread cell set, the wireless quality of a possibility multithread community is poor, and the wireless quality of another multithread community is better, so scheduling of resource just can be carried out in the good multithread community of preferred wireless quality in base station.

As shown in Figure 2 B, when each multithread community that user is corresponding belongs to different base stations, respectively scheduling of resource is carried out to the multithread community that self controls by each base station.The scheduling of resource priority of user in each multithread community self controlled periodically is determined in base station, and for each multithread community that self controls, respectively according to user's scheduling of resource priority in the cell, the downlink data transmission for this user dispatches the resource of this community.Wherein, the dispatching priority weight of the maximum downstream data throughput that base station can obtain in the multithread community self controlled according to user, the downlink data throughput obtained and correspondence, determines the scheduling of resource priority of user.

When multithread community is across base station, in each multithread community, selecting a community by network side is main plot, other Ze Weixie community, multithread community, for association community, it is lower that the dispatching priority weight of user is often arranged, to ensure the transfer of data of legacy user, that is the scheduling of resource priority of user in association community will be relatively low, therefore, the data of user send and can only be ensured in main plot, can be just only the downlink data transmission scheduling resource of user when assisting community to there is spare resources.

When multithread community is across base station, information interaction is not had between base station belonging to each multithread community, and the downlink data transmission situation in not knowing the multithread community that user controls in other base stations, therefore the scheduling of resource of fairness can not be carried out in each base station, and concrete condition is as follows:

(1) if main plot is congested, and assist community very idle, user obtains satisfied service in association community, but there is no information interaction between each base station belonging to each multithread community, user scheduling downlink data transmission resource still can be given in main plot, therefore assist community can not share the load of main plot, consume the resource that main plot is more, main plot can not obtain the gain that multithread HSDPA technology is brought.

(2) each community arrives the wireless quality of user is fluctuation, in each multithread community that user is corresponding, the wireless quality of one of them multithread community possible is poor, and the wireless quality of another multithread community is better, information interaction is not had between each base station belonging to each multithread community, therefore just preferably can not dispatch the resource of the good multithread community of wireless quality, make resource utilization lower, the spectrum efficiency of system is poor.

In sum, when multithread community is across base station, the scheduling of resource of carrying out fairness between the base station belonging to each multithread community is problem demanding prompt solution.

In prior art, when HSDPA passage is set up in user and multiple community simultaneously, and multithread community corresponding to user is when belonging to different base station (namely multithread community are across base station), the scheduling of resource priority in certain multithread community (being assumed to be multithread cell i) that user controls in this base station is determined in base station generally according to the following equation (1):

${\mathrm{priority}}_i=\frac{R_i}{r_i}*{\mathrm{SPIweight}}_i---\left(1\right)$

In formula (1), priority _ifor the scheduling of resource priority of user in multithread cell i; R _ifor the maximum downstream data throughput of this user in multithread cell i; SPIweight _ifor the dispatching priority weight of this user in multithread cell i; r _ifor the downlink data throughput of this user in multithread cell i.

Below the parameters in formula (1) is described in detail.

The maximum downstream data throughput R of user in multithread community refers to user's supported maximum downstream data throughput of its present position wireless quality in this multithread community; The downlink data throughput r of user in multithread community is the downlink data throughput that user has obtained in this multithread community; R/r is larger, illustrate that the downlink data throughput that the wireless quality of multithread community improves or user has obtained in this multithread community is too low, in order to ensure the fairness of scheduling of resource, now need to promote the dispatching priority of user in this multithread community, and R/r is less, then situation is contrary, needs to reduce the dispatching priority of user in this multithread community.

The factors such as the priority of the business that the dispatching priority weight SPIweight of user in multithread community is priority according to user, user sets up in multithread community are arranged, and are used for adjusting the value of R/r.

Because the downlink data transmission situation of user in multithread community is constantly change, therefore base station needs periodically to upgrade the scheduling of resource priority of user in multithread community, and the update cycle can preset.

Therefore, in prior art, if multithread community is across base station, then when the scheduling of resource priority of user in certain multithread community that this base station controls is determined in base station, only considered the downlink data throughput of user in this multithread community, information interaction is not had between base station belonging to each multithread community, therefore this base station downlink data transmission situation in not knowing the multithread community that user controls in other base stations, the scheduling of resource priority so determined just fairly can not embody the data transmission scenarios of user in each multithread community of correspondence, and then each base station can not be just the scheduling of resource that user carries out fairness according to scheduling of resource priority.

In embodiment of the present invention scheme, if multithread community is across base station, then when the scheduling of resource priority of user in certain multithread community that this base station controls is determined in base station, not only to consider the downlink data throughput in the multithread community that user controls in this base station, also to obtain the downlink data throughput in the multithread community that user controls in other base stations, the scheduling of resource priority so determined just can reflect the data transmission scenarios of user in each multithread community of correspondence, thus achieves between each base station as the transfer of data of user carries out the scheduling of resource of fairness.

When concrete enforcement the present invention program, if certain multithread small area jam, and another multithread community is idle, user obtains satisfied service in the multithread community of free time, so the downlink data throughput of user in congested multithread community is just larger, and then the scheduling of resource priority of user in congested multithread community is reduced, congested multithread community is no longer the too much downlink data transmission resource of this user scheduling, therefore the load of sharing user and bringing can be worked in coordination with in each multithread community, and each multithread community all can obtain the gain that multithread HSDPA technology is brought, in addition, if the wireless quality of certain multithread community is better, and the wireless quality of another multithread community is poor, user obtains satisfied service in wireless quality good multithread community, so the downlink data throughput of user in wireless quality good multithread community is just larger, and then the scheduling of resource priority of user in the poor multithread community of wireless quality is reduced, thus achieve the resource of the preferably scheduling good multithread community of wireless quality, improve resource utilization, improve the spectrum efficiency of system.

It should be noted that, the scheme of the embodiment of the present invention one can not only be applicable to universal mobile telecommunications system (Universal Mobile Telecommunications System, UMTS) the multithread technology across base station in, also the multithread technology across base station in Long Term Evolution (Long Term Evolution, LTE) system can be applicable to.

Be described in detail the present invention program below by specific embodiment, certainly, the present invention is not limited to following examples.

When multithread community is across base station, each multithread community corresponding to user belongs to different base stations, wherein each base station determines that the method for the scheduling of resource priority of user in the multithread community self controlled is consistent, and therefore, following embodiment is all that the angle standing in any one base station is described.

In the embodiment of the present invention, the scheduling of resource priority of user can be determined in base station by following two kinds of modes, be respectively:

The first determines the mode of scheduling of resource priority, base station first obtains the downlink data throughput in the multithread community that user controls in other base stations, then according to the downlink data throughput of this user in each multithread community of correspondence (comprising the downlink data throughput in the multithread community that downlink data throughput in the multithread community that this user controls in this base station and this user control in other base stations), the scheduling of resource priority of this user is determined;

The mode of the second determination scheduling of resource priority, base station first obtains the scheduling priority factor determined according to the downlink data throughput of this user in each multithread community of correspondence, then determines the scheduling of resource priority of this user according to the scheduling priority factor got.

Below above-mentioned two kinds of modes are described in detail respectively.

In prior art, when multithread community is across base station, can not carry out information interaction between each base station belonging to each multithread community, therefore the data transmission scenarios in the multithread community that user controls in other base stations is not just known in base station, and then cannot carry out the scheduling of resource of fairness.

In view of this, the embodiment of the present invention one proposes, when multithread community is across base station, downlink data throughput in direct mode or indirect mode can be adopted to obtain multithread community that user controls in other base stations, each base station belonging to multithread community, so the data transmission scenarios in the multithread community that user controls in other base stations just can be known in base station, thus provides basis for the scheduling of resource priority of the follow-up user of determination.

Below two kinds of modes of the downlink data throughput obtained in multithread community that user controls in other base stations are introduced respectively.

1, direct mode

Between each base station, increase physical interface in advance, set up physical connection by physical interface, such as, set up Fiber connection.Physical connection by setting up between each base station directly carries out information interaction.

Each base station belonging to each multithread community corresponding to user performs following operation respectively:

As shown in Figure 4 A, pass through physical connection, send the downlink data throughput in the multithread community that user controls in this base station to other base stations, and receive the downlink data throughput in the multithread community that other base stations are sent by physical connection, this user controls in other base stations described.

When multithread community is across base station, each base station controls at least one multithread community.If base station controls a multithread community, then the downlink data throughput of user in this multithread community self controlled can be sent to other base stations by base station.If base station controls at least two multithread communities, then the downlink data throughput of user in each multithread community self controlled can be sent to other base stations by base station, also the downlink data throughput sum of user in each multithread community self controlled can be sent to other base stations.

That is, in step 31, the downlink data throughput in the multithread community that this user that base station gets controls in other base stations can be following two kinds of situations:

Downlink data throughput in each multithread community that this user controls in other base stations; Or

Downlink data throughput sum in each multithread community that this user controls in other base stations.

A multithread community is controlled for base station, suppose that multithread community corresponding to user is community 1 and community 2, the base station belonging to community 1 is base station A, and the base station belonging to community 2 is base station B, base station A by the physical connection with base station B, by the downlink data throughput r of user in community 1 ₁send to base station B, base station B by the physical connection with base station A, by the downlink data throughput r of user in community 2 ₂send to base station A.

Two multithread communities are controlled for base station, suppose that multithread community is community 1, community 2 and community 3, community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B, base station B by the physical connection with base station A, by user downlink data throughput r in cell 3 ₃send to base station A, base station A by the physical connection with base station B, by the downlink data throughput r of user in community 1 ₁and the downlink data throughput r of user in community 2 ₂send to base station B, or base station A is by the physical connection with base station B, by the downlink data throughput r of user in community 1 ₁and the downlink data throughput r of user in community 2 ₂sum (r ₁+ r ₂) send to base station B.

In above-mentioned direct mode, by the downlink data throughput of physical connection direct interaction user between each base station, the propagation delay time of downlink data throughput can be reduced, simplify the handling process determining the scheduling of resource priority of user.

It should be noted that, in above-mentioned direct mode, can periodically mutual downlink data throughput between base station, concrete, base station can arrange the first transmission frequency for other base stations, then according to the first transmission frequency arranged for other base stations, the downlink data throughput in the multithread community periodically user controlled in this base station sends to other base stations described.The first transmission frequency that base station is arranged can reach every 2 milliseconds and sends once.

Further, the Congestion Level SPCC of the physical interface between all right basis in base station and other base stations, dynamically update the first transmission frequency arranged for other base stations, subsequent base stations according to the first transmission frequency after renewal, can send downlink data throughput to other base stations.If the physical interface between base station and other base stations is idle, then can improves the first transmission frequency arranged for other base stations, on the contrary, if the physical interface between base station and other base stations is congested, then can reduce the first transmission frequency arranged for other base stations.

Wherein, the Congestion Level SPCC of physical interface can characterize with the usage rate of physical interface, pre-set each usage rate scope, and be that each usage rate scope arranges corresponding transmission frequency respectively, when base station needs to upgrade the first transmission frequency arranged for other base stations, first can obtain the usage rate of the physical interface between other base stations, then the transmission frequency that usage rate scope belonging to this usage rate is corresponding is determined, using the transmission frequency determined as the first transmission frequency arranged for other base stations described after upgrading.Base station can pre-set a minimum guarantee transmission frequency, such as, be set to every 100 milliseconds send once, base station should be not less than this minimum guarantee transmission frequency for the first transmission frequency that other base stations are arranged, that is, when physical interface between base station and other base stations is very congested, downlink data throughput can be sent with this minimum guarantee transmission frequency.

Preferably, base station according to the update cycle of presetting, can periodically upgrade the first transmission frequency arranged for other base stations.

2, indirect mode

When multithread community is across base station, between each base station, tap into row information interaction by LA Management Room.Preferably, this network equipment can be radio network controller (Radio Network Controller, RNC).

As shown in Figure 4 B, each base station belonging to each multithread community corresponding to user sends the downlink data throughput of user in the multithread community self controlled respectively to RNC, after RNC receives the downlink data throughput that each base station sends respectively, for each base station, downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station, and each base station receives the downlink data throughput in the multithread community that RNC sends, this user controls in other base stations.

Preferably, information interaction can be carried out by existing Iub interface between each base station and RNC.

When multithread community is across base station, each base station controls at least one multithread community.If base station controls a multithread community, then the downlink data throughput of user in each multithread community self controlled can be sent to RNC by base station, then is transmitted to other base stations by RNC.If base station controls at least two multithread communities, then the downlink data throughput of user in each multithread community self controlled can be sent to RNC by base station, other base stations are transmitted to by RNC, the downlink data throughput sum of user in each multithread community self controlled also can be sent to RNC by base station, is transmitted to other base station by RNC.

Control a multithread community for base station, suppose that multithread community corresponding to user is community 1 and community 2, the base station belonging to community 1 is base station A, and the base station belonging to community 2 is base station B, base station A by Iub interface, by the downlink data throughput r of user in community 1 ₁send to RNC, base station B passes through Iub interface, by the downlink data throughput r of user in community 2 ₂send to RNC, RNC passes through Iub interface, by the downlink data throughput r of user in community 1 ₁send to base station B, by the downlink data throughput r of user in community 2 ₂send to base station A.

Two multithread communities are controlled for base station, suppose that multithread community is community 1, community 2 and community 3, community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B, base station B passes through Iub interface, by user downlink data throughput r in cell 3 ₃send to RNC, RNC by Iub interface by r ₃send to base station A, base station A passes through Iub interface, by the downlink data throughput r of user in community 1 ₁and the downlink data throughput r of user in community 2 ₂send to RNC, RNC by Iub interface by r ₁and r ₂send to base station B, or base station A is by Iub interface, by the downlink data throughput r of user in community 1 ₁and the downlink data throughput r of user in community 2 ₂sum (r ₁+ r ₂) send to RNC, RNC by Iub interface by (r ₁+ r ₂) send to base station B.

In above-mentioned indirect mode, by the downlink data throughput of RNC indirect interaction user between each base station, can ensure the compatibility with existing network to reduce the complexity determining scheduling of resource priority, namely reduce the complexity of carrying out scheduling of resource.

It should be noted that, in above-mentioned indirect mode, base station periodically can report downlink data throughput to RNC, concrete, base station can arrange the second transmission frequency, then according to the second transmission frequency arranged, the downlink data throughput in the multithread community periodically user controlled in this base station sends to RNC.The second transmission frequency that base station is arranged can reach every 2 milliseconds and sends once.

Further, the Congestion Level SPCC of the Iub interface between all right basis in base station and RNC, dynamically updates the second transmission frequency, and subsequent base stations according to the second transmission frequency after renewal, can report downlink data throughput to RNC.If the Iub interface between base station and RNC is idle, then can improves the second transmission frequency, on the contrary, if the Iub interface between base station and RNC is congested, then can reduce the second transmission frequency.

Wherein, the Congestion Level SPCC of Iub interface can characterize with the usage rate of Iub interface, pre-set each usage rate scope, and be that each usage rate scope arranges corresponding transmission frequency respectively, when base station needs renewal the second transmission frequency, first can obtain the usage rate of the Iub interface between RNC, then determine the transmission frequency that usage rate scope belonging to this usage rate is corresponding, using the transmission frequency determined as the second transmission frequency after upgrading.Base station can pre-set a minimum guarantee transmission frequency, such as, be set to every 100 milliseconds send once, the second transmission frequency that base station is arranged should be not less than this minimum guarantee transmission frequency, that is, when Iub interface between base station and RNC is very congested, minimumly can ensure that transmission frequency reports downlink data throughput with this.

Preferably, base station according to the update cycle of presetting, periodically can upgrade described second transmission frequency.

Step 32, downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations according to this user got and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

After base station gets the downlink data throughput in the multithread community that user controls in other base stations, downlink data throughput in the multithread community controlled in this base station self according to the downlink data throughput got and this user, determine the downlink data throughput sum of this user in each multithread community of correspondence, then the maximum downstream data throughput in the multithread community controlled in this base station self according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in this base station self.

The scheduling of resource priority in the multithread community that this user controls in this base station self is determined by following formula (2) in base station:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweigtht}}_i---\left(2\right)$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in this base station self; R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in this base station self; SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in this base station self; r _jfor the downlink data throughput of this user in the multithread community j of correspondence, the multithread community that multithread community j may control for this base station, the multithread community that also can control for other base stations; N is the quantity of multithread community corresponding to this user.

When multithread community is across base station, each base station controls at least one multithread community.If base station controls a multithread community, downlink data throughput then in the multithread community that controls in other base stations according to the downlink data throughput of user in this multithread community self controlled and user, base station, determines the scheduling of resource priority of user in this multithread community self controlled.If base station controls at least two multithread communities, then base station needs to determine the scheduling of resource priority of user in certain the multithread community self controlled according to following information: the downlink data throughput in the multithread community that the downlink data throughput of user in this multithread community self controlled, the downlink data throughput of user in other multithread communities self controlled, user control in other base stations.

Control a multithread community for base station, suppose that multithread community corresponding to user is community 1 and community 2, the n namely in above-mentioned formula (2) is 2, and the base station belonging to community 1 is base station A, and the base station belonging to community 2 is base station B.Base station A first calculates the downlink data throughput r of user in community 1 ₁with the downlink data throughput of user in community 2 and r ₂sum, obtains r ₁+ r ₂, then basis calculate the scheduling of resource priority priority of user in community 1 ₁; In like manner, base station B first calculates the downlink data throughput r of user in community 1 ₁with the downlink data throughput of user in community 2 and r ₂sum, obtains r ₁+ r ₂, then basis calculate the scheduling of resource priority priority of user in community 2 ₂.

Control two multithread communities for base station, suppose that multithread community is community 1, community 2 and community 3, the n namely in above-mentioned formula (2) is 3, and community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B.Base station A first calculates the downlink data throughput r of user in community 1 ₁, the downlink data throughput of user in community 2 and r ₂with user's downlink data throughput in cell 3 and r ₃sum, obtains r ₁+ r ₂+ r ₃, then basis calculate the scheduling of resource priority priority of user in community 1 ₁, according to calculate the scheduling of resource priority priority of user in community 2 ₂; In like manner, base station B first calculates the downlink data throughput r of user in community 1 ₁, the downlink data throughput of user in community 2 and r ₂with user's downlink data throughput in cell 3 and r ₃sum, obtains r ₁+ r ₂+ r ₃, then basis calculate user scheduling of resource priority priority in cell 3 ₃.

Therefore, in the embodiment of the present invention one scheme, when the scheduling of resource priority of user in certain multithread community that this base station controls is determined in base station, not only to consider the downlink data throughput in the multithread community that user controls in this base station, also will obtain the downlink data throughput in the multithread community that user controls in other base stations, the scheduling of resource priority so determined just can reflect the data transmission scenarios of user in each multithread community of correspondence.

Step 33, according to the scheduling of resource priority determined, is the resource of the multithread community that base station described in this user scheduling controls.

Base station, according to the scheduling of resource priority of user in the multithread community self controlled, is the process of the downlink data transmission scheduling resource of this user, consistent with the scheduling of resource process of prior art, repeats no more here.

The scheduling of resource priority determined due to base station can reflect the data transmission scenarios of user in each multithread community of correspondence, thus achieves between each base station as the transfer of data of user carries out the scheduling of resource of fairness.

Summary of the invention

The invention provides a kind of resource regulating method, information interacting method and equipment, in order to solve exist in prior art when multithread community is across base station, the problem of the scheduling of resource of fairness can not be carried out in each base station.

First aspect, provides a kind of resource regulating method, and described method comprises:

Base station belonging to multithread community corresponding to user obtains the downlink data throughput in the multithread community that this user controls in other base stations;

Downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations according to this user got and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

According to the scheduling of resource priority determined, it is the resource of the multithread community that base station described in this user scheduling controls.

In conjunction with first aspect, in the implementation that the first is possible, described base station obtains the downlink data throughput in the multithread community that this user controls in other base stations, specifically comprises:

Described base station receives the downlink data throughput in the multithread community that other base stations are sent by physical connection, this user controls in other base stations described.

In conjunction with the first possible implementation of first aspect, in the implementation that the second is possible, also comprise:

Described base station is according to the first transmission frequency arranged for described other base stations, and the downlink data throughput in multithread community user controlled in this base station sends to other base stations described.

In conjunction with the implementation that the second of first aspect is possible, in the implementation that the third is possible, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between other base stations described, upgrades the first transmission frequency arranged for other base stations described.

In conjunction with first aspect, in the 4th kind of possible implementation, described base station obtains the downlink data throughput in the multithread community that this user controls in other base stations, specifically comprises:

Described base station receives the downlink data throughput in the multithread community that radio network controller (RNC) sends, this user controls in other base stations.

In conjunction with the 4th kind of possible implementation of first aspect, in the 5th kind of possible implementation, also comprise:

Described base station is according to the second transmission frequency arranged, and the downlink data throughput in multithread community user controlled in this base station reports described RNC.

In conjunction with the 5th kind of possible implementation of first aspect, in the 6th kind of possible implementation, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between described RNC, upgrades described second transmission frequency.

In conjunction with the 6th kind of possible implementation of the third possible implementation of the possible implementation of the second of the first possible implementation of first aspect, first aspect, first aspect, first aspect, the 4th kind of possible implementation of first aspect, the 5th kind of possible implementation of first aspect or first aspect, in the 7th kind of possible implementation, the downlink data throughput in the multithread community that this user controls in other base stations is:

Downlink data throughput in each multithread community that this user controls in other base stations; Or

Downlink data throughput sum in each multithread community that this user controls in other base stations.

In conjunction with the 7th kind of possible implementation of the 4th kind of possible implementation of the third possible implementation of the possible implementation of the second of the first possible implementation of first aspect, first aspect, first aspect, first aspect, first aspect, the 5th kind of possible implementation of first aspect, the 6th kind of possible implementation of first aspect or first aspect, in the 8th kind of possible implementation, specifically comprise:

Downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations according to this user got and this user control in described base station, determines the downlink data throughput sum of this user in each multithread community of correspondence;

Maximum downstream data throughput in the multithread community controlled in described base station according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

In conjunction with the 8th kind of possible implementation of first aspect, in the 9th kind of possible implementation, the scheduling of resource priority in the multithread community that this user controls in described base station is determined by following manner in described base station:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweigtht}}_i$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Second aspect, provides a kind of information interacting method, and described method comprises:

Radio network controller (RNC) receives the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station;

Described RNC is for each base station belonging to each multithread community corresponding to this user, and the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

In conjunction with second aspect, in the first possible implementation of second aspect, described RNC is for each base station belonging to each multithread community corresponding to this user, and the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station, specifically comprises:

Described RNC is for each base station belonging to each multithread community corresponding to this user, and respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

In conjunction with the first possible implementation of second aspect, in the implementation that the second is possible, also comprise:

Described RNC for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

The third aspect, a kind of resource regulating method, described method comprises:

Base station belonging to multithread community corresponding to user obtains the scheduling priority factor in the multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence;

Scheduling priority factor in the multithread community controlled in described base station according to this user got, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

According to the scheduling of resource priority determined, it is the resource of the multithread community that base station described in this user scheduling controls.

In conjunction with the third aspect, in the first possible implementation of the third aspect, described scheduling priority factor is the downlink data throughput sum of user in each multithread community of correspondence.

In conjunction with the first possible implementation of the third aspect, in the implementation that the second is possible, described base station obtains the scheduling priority factor in the multithread community that this user controls in described base station, specifically comprises:

Described base station receives scheduling priority factor that radio network controller (RNC) sends, that determine according to the downlink data throughput of this user in each multithread community of correspondence.

In conjunction with the implementation that the second of the third aspect is possible, in the implementation that the third is possible, also comprise:

Described base station is according to the first transmission frequency arranged, and the downlink data throughput in multithread community user controlled in this base station reports described RNC.

In conjunction with the third possible implementation of the third aspect, in the 4th kind of possible implementation, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between described RNC, upgrades described first transmission frequency.

In conjunction with implementation, the third possible implementation of the third aspect or the 4th kind of possible implementation of the third aspect that the second of the first possible implementation of the third aspect, the third aspect is possible, in the 5th kind of possible implementation, scheduling priority factor in the multithread community controlled in described base station according to this user got, determine the scheduling of resource priority in the multithread community that this user controls in described base station, specifically comprise:

Maximum downstream data throughput in the multithread community that scheduling priority factor in the multithread community controlled in described base station according to this user got and this user control in described base station and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

In conjunction with the 5th kind of possible implementation of the third aspect, in the 6th kind of possible implementation, the scheduling of resource priority in the multithread community that this user controls in described base station is determined by following manner in described base station:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i$

$Z_i=\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

In conjunction with the third aspect, in the 7th kind of possible implementation, the ratio of the dispatching priority weight in the described scheduling priority factor multithread community that to be this user control in described base station and the downlink data throughput sum of this user in corresponding each multithread community.

In conjunction with the 7th kind of possible implementation of the third aspect, in the 8th kind of possible implementation, described base station obtains the scheduling priority factor in the multithread community that this user controls in described base station, specifically comprises:

Described base station receives the scheduling priority factor that the dispatching priority weight in multithread community that radio network controller (RNC) sends, that control in described base station according to this user and the downlink data throughput in each multithread community of this user in correspondence are determined.

In conjunction with the 8th kind of possible implementation of the third aspect, in the 9th kind of possible implementation, also comprise:

Described base station is according to the second transmission frequency arranged, and the dispatching priority weight in multithread community user controlled in this base station and downlink data throughput report described RNC.

In conjunction with the 9th kind of possible implementation of the third aspect, in the tenth kind of possible implementation, also comprise: described base station, according to the Congestion Level SPCC of the interface between described RNC, upgrades described second transmission frequency.

In conjunction with the tenth kind of possible implementation of the 7th kind of possible implementation of the third aspect, the 8th kind of possible implementation of the third aspect, the 9th kind of possible implementation of the third aspect or the third aspect, in the 11 kind of possible implementation, scheduling priority factor in the multithread community controlled in described base station according to this user got, determine the scheduling of resource priority in the multithread community that this user controls in described base station, specifically comprise:

Maximum downstream data throughput in the multithread community that scheduling priority factor in the multithread community controlled in described base station according to this user got and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

In conjunction with the 11 kind of possible implementation of the third aspect, in the 12 kind of possible implementation, the scheduling of resource priority in the multithread community that this user controls in described base station is determined by following manner in described base station:

priority _i＝R _i*Z _i

$Z_i={\mathrm{SPIweight}}_i/\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Fourth aspect, provides a kind of information interacting method, and described method comprises:

Radio network controller (RNC) receives the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station;

Described RNC is for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, and the scheduling priority factor determined is sent to this base station.

In conjunction with fourth aspect, in the implementation that the first is possible, the scheduling priority factor determined is sent to this base station by described RNC, specifically comprises:

The scheduling priority factor determined, according to the transmission frequency arranged for this base station, is sent to this base station by described RNC.

In conjunction with the first possible implementation of fourth aspect, in the implementation that the second is possible, also comprise:

Described RNC for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

In conjunction with the first possible implementation of fourth aspect, fourth aspect or the possible implementation of the second of fourth aspect, in the implementation that the third is possible, according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, specifically comprise:

Determine the downlink data throughput sum of this user in each multithread community of correspondence;

By the described downlink data throughput sum determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

In conjunction with the first possible implementation of fourth aspect, fourth aspect or the possible implementation of the second of fourth aspect, in the 4th kind of possible implementation, receive the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station, specifically comprise:

Receive the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station and dispatching priority weight;

According to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, specifically comprise:

Determine the ratio of the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community;

By the described ratio determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

5th aspect, provides a kind of base station, comprising:

Throughput acquiring unit, for obtaining the downlink data throughput in multithread community that this user controls in other base stations;

Dispatching priority determining unit, downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations for this user of getting according to throughput acquiring unit and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

Scheduling of resource unit, for the scheduling of resource priority determined according to dispatching priority determining unit, is the resource of the multithread community that base station described in this user scheduling controls.

In conjunction with the 5th aspect, in the implementation that the first is possible, described base station also comprises:

First throughput transmitting element, for by physical connection, sends to other base stations by the downlink data throughput of user in the multithread community self controlled;

Described throughput acquiring unit, specifically for receiving the downlink data throughput in multithread community that other base stations send, this user controls in other base stations described.

In conjunction with the first possible implementation of the 5th aspect, in the implementation that the second is possible, described first throughput transmitting element, specifically for according to the first transmission frequency arranged for other base stations, the downlink data throughput in multithread community user controlled in this base station sends to other base stations described.

In conjunction with the implementation that the second of the 5th aspect is possible, in the implementation that the third is possible, described base station also comprises:

First transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and other base stations, upgrades the first transmission frequency arranged for other base stations described.

The implementation possible in conjunction with the second of the first possible implementation of the 5th aspect, the 5th aspect or the third possible implementation of the 5th aspect, in the 4th kind of possible implementation, described first throughput transmitting element, specifically for sending to other base stations by the downlink data throughput of this user in each multithread community self controlled; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to other base stations.

In conjunction with the 4th kind of possible implementation of the 5th aspect, in the 5th kind of possible implementation, described base station also comprises:

Second throughput transmitting element, for reporting radio network controller (RNC) by the downlink data throughput of user in the multithread community self controlled;

Described throughput acquiring unit, specifically for receiving the downlink data throughput in multithread community that RNC sends, this user controls in other base stations.

In conjunction with the 5th kind of possible implementation of the 5th aspect, in the 6th kind of possible implementation, second throughput transmitting element, specifically for according to the second transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

In conjunction with the 6th kind of possible implementation of the 5th aspect, in the 7th kind of possible implementation, described base station also comprises:

Second transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

In conjunction with the 7th kind of possible implementation of the 5th kind of possible implementation of the 5th aspect, the 6th kind of possible implementation of the 5th aspect or the 5th aspect, in the 8th kind of possible implementation, described second throughput transmitting element, specifically for sending to RNC by the downlink data throughput of this user in each multithread community self controlled; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to RNC.

In conjunction with the 5th aspect, the first possible implementation of 5th aspect, the implementation that the second of 5th aspect is possible, the third possible implementation of 5th aspect, 4th kind of possible implementation of the 5th aspect, 5th kind of possible implementation of the 5th aspect, 6th kind of possible implementation of the 5th aspect, 7th kind of possible implementation of the 5th aspect or the 8th kind of possible implementation of the 5th aspect, in the 9th kind of possible implementation, dispatching priority determining unit, downlink data throughput in the multithread community controlled in described base station specifically for the downlink data throughput in the multithread community that controls in other base stations according to this user of getting and this user, determine the downlink data throughput sum of this user in each multithread community of correspondence, maximum downstream data throughput in the multithread community controlled in described base station according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

In conjunction with the 9th kind of possible implementation of the 5th aspect, in the tenth kind of possible implementation, described dispatching priority determining unit determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweigtht}}_i$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

6th aspect, provides a kind of radio network controller, comprising:

Throughput receiving element, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Throughput transmitting element, for for each base station belonging to each multithread community corresponding to this user, the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

In conjunction with the 6th aspect, in the implementation that the first is possible, described throughput transmitting element, specifically for for each base station belonging to each multithread community corresponding to this user, respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

In conjunction with the first possible implementation of the 6th aspect, in the implementation that the second is possible, also comprise:

Transmission frequency updating block, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

7th aspect, provides a kind of base station, comprising:

Priority factors acquiring unit, for obtaining the scheduling priority factor in multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence;

Dispatching priority determining unit, the scheduling priority factor in the multithread community controlled in described base station for this user of getting according to priority factors acquiring unit, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

Scheduling of resource unit, for the scheduling of resource priority determined according to dispatching priority determining unit, is the resource of the multithread community that base station described in this user scheduling controls.

In conjunction with the 7th aspect, in the first the possible implementation in the 7th, described scheduling priority factor is the downlink data throughput sum of user in each multithread community of correspondence.

In conjunction with the first possible implementation of the 7th aspect, in the implementation that the second is possible, described base station also comprises:

First throughput transmitting element, for sending to radio network controller (RNC) by the downlink data throughput of user in the multithread community self controlled;

Described priority factors acquiring unit, specifically for receiving scheduling priority factor that RNC sends, that determine according to the downlink data throughput of this user in each multithread community of correspondence.

In conjunction with the implementation that the second of the 7th aspect is possible, in the implementation that the third is possible, described first throughput transmitting element, specifically for according to the first transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

In conjunction with the third possible implementation of the 7th aspect, in the 4th kind of possible implementation, also comprise:

First transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described first transmission frequency.

In conjunction with the first possible implementation of the 7th aspect, the implementation that the second of 7th aspect is possible, the third possible implementation of 7th aspect or the 4th kind of possible implementation of the 7th aspect, in the 5th kind of possible implementation, described dispatching priority determining unit, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user of getting and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

In conjunction with the 5th kind of possible implementation of the 7th aspect, in the 6th kind of possible implementation, described dispatching priority determining unit determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i$

$Z_i=\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

In conjunction with the 7th aspect, in the 7th kind of possible implementation, the ratio of the dispatching priority weight in the described scheduling priority factor multithread community that to be this user control in described base station and the downlink data throughput sum of this user in corresponding each multithread community.

In conjunction with the 7th kind of possible implementation of the 7th aspect, in the 8th kind of possible implementation, described base station also comprises:

Second throughput transmitting element, for sending to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput;

Described priority factors acquiring unit, specifically for receiving the scheduling priority factor that the dispatching priority weight in multithread community that RNC sends, that control in described base station according to this user and the downlink data throughput in each multithread community of this user in correspondence are determined.

In conjunction with the 8th kind of possible implementation of the 7th aspect, in the 9th kind of possible implementation, described second throughput transmitting element, specifically for according to the second transmission frequency arranged, the dispatching priority weight of user in the multithread community self controlled and downlink data throughput are sent to RNC.

In conjunction with the 9th kind of possible implementation of the 7th aspect, in the tenth kind of possible implementation, also comprise:

Second transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

In conjunction with the 7th kind of possible implementation of the 7th aspect, 8th kind of possible implementation of the 7th aspect, 9th kind of possible implementation of the 7th aspect or the tenth kind of possible implementation of the 7th aspect, in the 11 kind of possible implementation, described dispatching priority determining unit, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user of getting and this user, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

In conjunction with the 11 kind of possible implementation of the 7th aspect, in the 12 kind of possible implementation, described dispatching priority determining unit determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

priority _i＝R _i*Z _i

$Z_i={\mathrm{SPIweight}}_i/\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Eighth aspect, provides a kind of radio network controller, comprising:

Throughput receiving element, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Scheduling priority factor determining unit, for for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station;

Scheduling priority factor transmitting element, the scheduling priority factor for scheduling priority factor determining unit being determined sends to this base station.

In conjunction with eighth aspect, in the implementation that the first is possible, described scheduling priority factor transmitting element, specifically for according to the transmission frequency arranged for this base station, sends to this base station by the scheduling priority factor determined.

In conjunction with the first possible implementation of eighth aspect, in the implementation that the second is possible, also comprise:

Transmission frequency adjustment unit, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

In conjunction with the first possible implementation of eighth aspect, eighth aspect or the possible implementation of the second of eighth aspect, in the implementation that the third is possible, described scheduling priority factor determining unit, specifically for determining the downlink data throughput sum of this user in each multithread community of correspondence; By the described downlink data throughput sum determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

In conjunction with the first possible implementation of eighth aspect, eighth aspect or the possible implementation of the second of eighth aspect, in the 4th kind of possible implementation, described throughput receiving element, the downlink data throughput in that send respectively specifically for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community and dispatching priority weight;

Described scheduling priority factor determining unit, specifically for determining the ratio of the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community; By the described ratio determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

By the scheme of the embodiment of the present invention, when HSDPA passage is set up in user and multiple community simultaneously, and multithread community corresponding to user is when belonging to different base stations, scheduling of resource priority in the multithread community that user controls in certain base station not only will consider the downlink data throughput in the multithread community that user controls in this base station, also to consider the downlink data throughput in the multithread community that user controls in other base stations, the scheduling of resource priority so determined just can reflect the data transmission scenarios of user in each multithread community of correspondence, thus achieve between each base station as the transfer of data of user carries out the scheduling of resource of fairness, if certain multithread small area jam, and another multithread community is idle, user obtains satisfied service in the multithread community of free time, so the downlink data throughput of user in congested multithread community is just larger, and then the scheduling of resource priority of user in congested multithread community is reduced, congested multithread community is no longer the too much downlink data transmission resource of this user scheduling, therefore the load of sharing user and bringing can be worked in coordination with in each multithread community, and each multithread community all can obtain the gain that multithread HSDPA technology is brought, in addition, if the wireless quality of certain multithread community is better, and the wireless quality of another multithread community is poor, user obtains satisfied service in wireless quality good multithread community, so the downlink data throughput of user in wireless quality good multithread community is just larger, and then the scheduling of resource priority of user in the poor multithread community of wireless quality is reduced, thus achieve the resource of the preferably scheduling good multithread community of wireless quality, improve resource utilization, improve the spectrum efficiency of system.

Accompanying drawing explanation

In order to be illustrated more clearly in the technical scheme in the embodiment of the present invention, below the accompanying drawing used required in describing embodiment is briefly introduced, apparently, accompanying drawing in the following describes is only some embodiments of the present invention, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings.

Fig. 1 is in prior art, and the schematic diagram of HSDPA passage is set up in user and community;

Fig. 2 A is in prior art, and each multithread community in multithread cell set belongs to schematic diagram during same base station;

Fig. 2 B is in prior art, and each multithread community in multithread cell set belongs to schematic diagram during different base station;

Fig. 3 is in the embodiment of the present invention one, resource regulating method schematic flow sheet;

Fig. 4 A is in the embodiment of the present invention one, is directly carried out the schematic diagram of information interaction between each base station by physical connection;

Fig. 4 B is in the embodiment of the present invention one, is indirectly carried out the schematic diagram of information interaction between each base station by RNC;

Fig. 5 is in the embodiment of the present invention two, information interacting method schematic flow sheet;

Fig. 6 is in the embodiment of the present invention three, resource regulating method schematic flow sheet;

Fig. 7 A is in the embodiment of the present invention three, when scheduling priority factor is the first form, carries out the schematic diagram of information interaction between each base station and RNC;

Fig. 7 B is in the embodiment of the present invention three, when scheduling priority factor is the second form, carries out the schematic diagram of information interaction between each base station and RNC;

Fig. 8 is in the embodiment of the present invention four, information interacting method schematic flow sheet;

Fig. 9 and Figure 10 is in the embodiment of the present invention five, the structural representation of base station;

Figure 11 and Figure 12 is in the embodiment of the present invention six, the structural representation of RNC;

Figure 13 and Figure 14 is in the embodiment of the present invention seven, the structural representation of base station;

Figure 15 and Figure 16 is in the embodiment of the present invention eight, the structural representation of RNC.

Embodiment

In order to make the object, technical solutions and advantages of the present invention clearly, below in conjunction with accompanying drawing, the present invention is described in further detail, and obviously, described embodiment is only a part of embodiment of the present invention, instead of whole embodiments.Based on the embodiment in the present invention, those of ordinary skill in the art, not making other embodiments all obtained under creative work prerequisite, belong to the scope of protection of the invention.

Embodiment one:

First the mode that the first determines scheduling of resource priority is introduced, base station first obtains the downlink data throughput in the multithread community that user controls in other base stations, then according to the downlink data throughput of this user in each multithread community of correspondence, the scheduling of resource priority of this user is determined.

As shown in Figure 3, be the step schematic diagram of resource regulating method in the embodiment of the present invention one, said method comprising the steps of:

Step 31, the base station belonging to multithread community corresponding to user obtains the downlink data throughput in the multithread community that this user controls in other base stations.

Embodiment two:

In the embodiment of the present invention one scheme, by the downlink data throughput of RNC indirect interaction user between base station, the embodiment of the present invention two describes the method for carrying out information interaction between RNC and base station, as shown in Figure 5, comprises the following steps:

Step 51, RNC receives the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station.

Step 52, described RNC is for each base station belonging to each multithread community corresponding to this user, and the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

Preferably, information interaction can be carried out by existing Iub interface between each base station and RNC.

It should be noted that, RNC can periodically to each base station converting downlink data throughput, concrete, RNC is for each base station belonging to each multithread community corresponding to user, corresponding transmission frequency is set respectively, then for each base station, respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

Further, RNC can also dynamically update the transmission frequency arranged respectively for each base station, concrete, RNC is for each base station belonging to each multithread community corresponding to user, the Congestion Level SPCC of the Iub interface respectively between basis and this base station, dynamically update the transmission frequency arranged for this base station, follow-up RNC can to forward the downlink data throughput that other base stations report to this base station according to the transmission frequency after upgrading.If the Iub interface between RNC and base station is idle, then the transmission frequency arranged for base station can be improved, on the contrary, if the Iub interface between RNC and base station is congested, then the transmission frequency arranged for base station can be reduced.

Wherein, the Congestion Level SPCC of Iub interface can characterize with the usage rate of Iub interface, pre-set each usage rate scope, and be that each usage rate scope arranges corresponding transmission frequency respectively, when RNC needs to upgrade the transmission frequency arranged for certain base station, first can obtain the usage rate of the Iub interface between this base station, then the transmission frequency that usage rate scope belonging to this usage rate is corresponding is determined, using the transmission frequency determined as the transmission frequency arranged for this base station after upgrading.RNC can pre-set a minimum guarantee transmission frequency, such as, be set to every 100 milliseconds send once, RNC should be not less than this minimum guarantee transmission frequency for the transmission frequency that base station is arranged, that is, when Iub interface between RNC and base station is very congested, can to forward with this minimum guarantee transmission frequency the downlink data throughput that other base stations report to base station.

Preferably, RNC according to the update cycle of presetting, can periodically upgrade the transmission frequency arranged for each base station.

Embodiment three:

Introduce the mode of the second determination scheduling of resource priority below, base station first obtains the scheduling priority factor determined according to the downlink data throughput of this user in each multithread community of correspondence, then determines the scheduling of resource priority of this user according to the scheduling priority factor got.

As shown in Figure 6, be the step schematic diagram of resource regulating method in the embodiment of the present invention three, said method comprising the steps of:

Step 61, base station belonging to multithread community corresponding to user obtains the scheduling priority factor in the multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence.

The embodiment of the present invention three proposes, when multithread community is across base station, each base station belonging to multithread community can obtain the scheduling priority factor determined according to the downlink data throughput of this user in each multithread community of correspondence, so the data transmission scenarios of user in each multithread community of correspondence just can be known in base station, thus provides basis for the scheduling of resource priority of the follow-up user of determination.

In a step 61, each base station belonging to each multithread community corresponding to user respectively can by the network equipment according to the downlink data throughput of user in each multithread community of correspondence by the downlink data throughput of this user in the multithread community self controlled, determine the scheduling priority factor of user in each multithread community, and then the scheduling priority factor determined is sent to corresponding base station.Preferably, this network equipment can be RNC.

Wherein, information interaction can be carried out by existing Iub interface between each base station and RNC.

Because scheduling priority factor determines according to the downlink data throughput of user in each multithread community of correspondence, therefore each base station belonging to each multithread community that user is corresponding needs to send the downlink data throughput of user in the multithread community self controlled respectively to RNC, the downlink data throughput that RNC sends respectively according to each base station, determines the scheduling priority factor of user in each multithread community.

In the embodiment of the present invention three, scheduling priority factor can be, but not limited to as following two kinds of forms:

The first form, the scheduling priority factor in the multithread community that user controls in base station is the downlink data throughput sum in each multithread community of user in correspondence;

The second form, the ratio of the dispatching priority weight in the multithread community that to be user control in this base station of the scheduling priority factor in the multithread community that user controls in base station and the downlink data throughput sum of this user in corresponding each multithread community.

When introducing scheduling priority factor below respectively for often kind of form, the information interaction situation of base station and RNC and RNC determine the process of scheduling priority factor.

1, when scheduling priority factor is the first form above-mentioned, as shown in Figure 7 A, each base station belonging to each multithread community that user is corresponding needs to send the downlink data throughput of user in the multithread community self controlled respectively to RNC, after RNC receives the downlink data throughput that each base station sends respectively, determine the downlink data throughput sum of this user in each multithread community of correspondence, then the downlink data throughput sum determined is sent to each base station as scheduling priority factor.

It should be noted that, base station periodically can report downlink data throughput to RNC, concrete, base station can arrange the first transmission frequency for RNC, then according to the first transmission frequency arranged, the downlink data throughput in the multithread community periodically user controlled in this base station sends to RNC.The first transmission frequency that base station is arranged can reach every 2 milliseconds and sends once.

Further, the Congestion Level SPCC of the Iub interface between all right basis in base station and RNC, dynamically updates the first transmission frequency, and subsequent base stations according to the first transmission frequency after renewal, can report downlink data throughput to RNC.If the Iub interface between base station and RNC is idle, then can improves the first transmission frequency, on the contrary, if the Iub interface between base station and RNC is congested, then can reduce the first transmission frequency.

Wherein, the Congestion Level SPCC of Iub interface can characterize with the usage rate of Iub interface, pre-set each usage rate scope, and be that each usage rate scope arranges the first corresponding transmission frequency respectively, when base station needs renewal the first transmission frequency, first can obtain the usage rate of the Iub interface between RNC, then determine the transmission frequency that usage rate scope belonging to this usage rate is corresponding, using the transmission frequency determined as the first transmission frequency after upgrading.Base station can pre-set a minimum guarantee transmission frequency, such as, be set to every 100 milliseconds send once, the first transmission frequency that base station is arranged should be not less than this minimum guarantee transmission frequency, that is, when Iub interface between base station and RNC is very congested, minimumly can ensure that transmission frequency reports downlink data throughput with this.

Preferably, base station according to the update cycle of presetting, periodically can upgrade described transmission frequency.

When multithread community is across base station, each base station controls at least one multithread community, the downlink data throughput of user in each multithread community self controlled is sent to RNC by each base station, determines scheduling priority factor by RNC, the scheduling priority factor that each multithread community is corresponding identical.

Control a multithread community for base station, suppose that multithread community corresponding to user is community 1 and community 2, the base station belonging to community 1 is base station A, and the base station belonging to community 2 is base station B, base station A by Iub interface, by the downlink data throughput r of user in community 1 ₁send to RNC, base station B passes through Iub interface, by the downlink data throughput r of user in community 2 ₂send to RNC, RNC determines the downlink data throughput sum r of user in each multithread community of correspondence ₁+ r ₂, then by Iub interface, by r ₁+ r ₂base station A and base station B is sent to as scheduling priority factor.

Two multithread communities are controlled for base station, suppose that multithread community is community 1, community 2 and community 3, community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B, base station A passes through Iub interface, by the downlink data throughput r of user in community 1 ₁and the downlink data throughput r of user in community 2 ₂send to RNC, base station B passes through Iub interface, by user downlink data throughput r in cell 3 ₃send to RNC, RNC determines the downlink data throughput sum r of user in each multithread community of correspondence ₁+ r ₂+ r ₃, then RNC is by Iub interface, by r ₁+ r ₂+ r ₃base station A and base station B is sent to as scheduling priority factor.

2, when scheduling priority factor is above-mentioned the second form, RNC determines that scheduling priority factor needs to know the downlink data throughput of user in each multithread community of correspondence and dispatching priority weight, therefore, as shown in Figure 7 B, each base station belonging to each multithread community corresponding to user does not simply need to RNC and sends the downlink data throughput of user in the multithread community self controlled, the dispatching priority weight of user in the multithread community self controlled also is needed to send to RNC in the lump, after RNC receives the downlink data throughput and dispatching priority weight that each base station sends respectively, determine the downlink data throughput sum of user in each multithread community of correspondence, then following operation is performed respectively for each base station: the ratio determining the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community, again the ratio determined is sent to this base station as scheduling priority factor.

It should be noted that, base station can periodically to RNC reporting scheduling priority weighting and downlink data throughput, concrete, base station can arrange the second transmission frequency for RNC, then according to the second transmission frequency arranged, the dispatching priority weight in the multithread community periodically user controlled in this base station and downlink data throughput send to RNC.

Further, base station can also according to and RNC between the Congestion Level SPCC of Iub interface, dynamically update the second transmission frequency, subsequent base stations can according to the second transmission frequency after upgrading, to RNC reporting scheduling priority weighting and downlink data throughput.

Wherein, the idiographic flow upgrading the second transmission frequency is similar with the idiographic flow upgrading above-mentioned first transmission frequency, repeats no more here.

Preferably, base station according to the update cycle of presetting, periodically can upgrade described second transmission frequency.

When multithread community is across base station, each base station controls at least one multithread community, the downlink data throughput of user in each multithread community self controlled and dispatching priority weight are sent to RNC by each base station, the scheduling priority factor of user in each multithread community is determined, the scheduling priority factor that each multithread community is corresponding different by RNC.

Control a multithread community for base station, suppose that multithread community corresponding to user is community 1 and community 2, the base station belonging to community 1 is base station A, and the base station belonging to community 2 is base station B, base station A by Iub interface, by the downlink data throughput r of user in community 1 ₁with dispatching priority weight SPIweight ₁, base station B passes through Iub interface, by the downlink data throughput r of user in community 2 ₂with dispatching priority weight SPIweight ₂send to RNC, RNC determines the scheduling priority factor of user in community 1 and the scheduling priority factor of user in community 2 rNC passes through Iub interface, by the Z determined ₁send to base station A, by the Z determined ₂send to base station B.

Two multithread communities are controlled for base station, suppose that multithread community is community 1, community 2 and community 3, community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B, base station A passes through Iub interface, by the downlink data throughput r of user in community 1 ₁with dispatching priority weight SPIweight ₁, the downlink data throughput r of user in community 2 ₂with dispatching priority weight SPIweight ₂send to RNC, base station B passes through Iub interface, by user downlink data throughput r in cell 3 ₃with dispatching priority weight SPIweight ₃send to RNC, RNC determines the scheduling priority factor of user in community 1 the scheduling priority factor of user in community 2 and user's scheduling priority factor in cell 3 rNC passes through Iub interface, by the Z determined ₁and Z ₂send to base station A, by the Z determined ₃send to base station B.

Step 62, the scheduling priority factor in the multithread community controlled in described base station according to this user got, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

In the embodiment of the present invention three scheme, after RNC determines scheduling priority factor according to the downlink data throughput that each base station reports, scheduling priority factor is sent to corresponding base station, corresponding scheduling of resource priority is determined according to scheduling priority factor in base station, therefore, it is possible to simplify the handling process that scheduling of resource priority is determined in base station.

Introduce respectively below scheduling priority factor be the first form above-mentioned or the second form time, the process of scheduling of resource priority is determined in base station.

1, scheduling priority factor is the first form above-mentioned, and the scheduling of resource priority namely in the multithread community that controls in base station of user is the downlink data throughput sum in each multithread community of user in correspondence.After base station gets the scheduling priority factor in the multithread community that this user controls in this base station self, maximum downstream data throughput in the multithread community controlled in this base station according to the scheduling priority factor got and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in this base station self.

The scheduling of resource priority in the multithread community that this user controls in this base station self is determined by following formula (3) in base station:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i---\left(3\right)$

Wherein, priority _ifor this user this base station self control multithread cell i in scheduling of resource priority; R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in this base station self; Z _ifor the scheduling priority factor in the multithread cell i that this user controls in this base station self, r _jfor the downlink data throughput of this user in the multithread community j of correspondence, multithread community j may be the multithread community that this base station controls, and can be also the multithread community of other base stations control, n be the quantity of multithread community corresponding to this user; SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in this base station self.

2, scheduling priority factor is above-mentioned the second form, the ratio of the dispatching priority weight in the multithread community that to be this user control in this base station of the scheduling of resource priority namely in the multithread community that controls in base station of user and the downlink data throughput sum of this user in corresponding each multithread community.After base station gets the scheduling priority factor in the multithread community that this user controls in this base station self, maximum downstream data throughput in the multithread community controlled in this base station according to the scheduling priority factor got and this user, determines the scheduling of resource priority in the multithread community that this user controls in this base station self.

The scheduling of resource priority in the multithread community that this user controls in this base station self is determined by following formula (4) in base station:

priority _i＝R _i*Z _i(4)

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in this base station self; R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in this base station self; Z _ifor the scheduling priority factor in the multithread cell i that this user controls in this base station self, r _jfor the downlink data throughput of this user in the multithread community j of correspondence, multithread community j may be the multithread community that this base station controls, and can be also the multithread community of other base stations control, n be the quantity of multithread community corresponding to this user, SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in this base station self.

Therefore, in the embodiment of the present invention three scheme, when the scheduling of resource priority of user in certain multithread community that this base station controls is determined in base station, not only to consider the downlink data throughput in the multithread community that user controls in this base station, also will consider the downlink data throughput in the multithread community that user controls in other base stations, the scheduling of resource priority so determined just can reflect the data transmission scenarios of user in each multithread community of correspondence.

Step 63, according to the scheduling of resource priority determined, is the resource of the multithread community that base station described in this user scheduling controls.

Base station, according to the scheduling of resource priority of user in the multithread community self controlled, is the process of the downlink data transmission scheduling resource of this user, consistent with the scheduling of resource process of prior art, repeats no more here.

The scheduling of resource priority determined due to base station can reflect the data transmission scenarios of user in each multithread community of correspondence, thus achieves between each base station as the transfer of data of user carries out the scheduling of resource of fairness.

Embodiment four:

In the embodiment of the present invention three scheme, each base station can by RNC according to the downlink data throughput of user in each multithread community of correspondence, determine the scheduling priority factor of user in each multithread community, the embodiment of the present invention four describes the method for carrying out information interaction between RNC and base station, as shown in Figure 8, comprise the following steps:

Step 81, RNC receives the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station.

Step 82, described RNC is for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, and the scheduling priority factor determined is sent to this base station.

Preferably, information interaction can be carried out by existing Iub interface between each base station and RNC.

When introducing scheduling priority factor below respectively for the first form described in the embodiment of the present invention three or the second form, RNC determines the process of scheduling priority factor.

1, scheduling priority factor is the first form above-mentioned, and the scheduling of resource priority namely in the multithread community that controls in base station of user is the downlink data throughput sum in each multithread community of user in correspondence.After RNC receives the downlink data throughput that each base station sends respectively, determine the downlink data throughput sum of this user in each multithread community of correspondence, by the described downlink data throughput sum determined, confirm as the scheduling priority factor of this user in each multithread community.Therefore, the scheduling priority factor that each multithread community is corresponding identical.

Such as, multithread community is community 1, community 2 and community 3, and community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B.RNC, by Iub interface, receives the downlink data throughput r of user in community 1 that base station A sends ₁and the downlink data throughput r of user in community 2 ₂, receive the user downlink data throughput r in cell 3 that base station B sends ₃, RNC calculates the downlink data throughput sum r of this user in each multithread community of correspondence ₁+ r ₂+ r ₃, then by r ₁+ r ₂+ r ₃confirm as the scheduling priority factor of user in each multithread community, i.e. Z ₁=Z ₂=Z ₃=r ₁+ r ₂+ r ₃.

2, scheduling priority factor is above-mentioned the second form, the ratio of the dispatching priority weight in the multithread community that to be this user control in this base station of the scheduling of resource priority namely in the multithread community that controls in base station of user and the downlink data throughput sum of this user in corresponding each multithread community.Each base station not only will send the downlink data throughput in the multithread community that this user controls in this base station to RNC, also to send the dispatching priority weight in the multithread community that this user controls in this base station, after RNC receives the downlink data throughput and dispatching priority weight that each base station sends respectively, following operation is performed respectively: the ratio determining the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community for each base station, then the described ratio will determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

Such as, multithread community is community 1, community 2 and community 3, and community 1 and the base station belonging to community 2 are base station A, and the base station belonging to community 3 is base station B.RNC by Iub interface, receives downlink data throughput r1 in community 1 of user that base station A sends and dispatching priority weight SPIweight ₁, and the downlink data throughput r2 of user in community 2 and dispatching priority weight SPIweight ₂, receive user downlink data throughput r3 in cell 3 and dispatching priority weight SPIweight that base station B sends ₃, RNC calculates the dispatching priority weight of user in community 1 and the ratio of the downlink data throughput sum of this user in corresponding each multithread community the ratio of the dispatching priority weight of user in community 2 and the downlink data throughput sum of this user in corresponding each multithread community the ratio of user's dispatching priority weight in cell 3 and the downlink data throughput sum of this user in corresponding each multithread community then RNC will confirm as the scheduling priority factor of user in community 1, namely will confirm as the scheduling priority factor of user in community 2, namely will confirm as user's scheduling priority factor in cell 3, namely $Z_3=\frac{{\mathrm{SPIweight}}_3}{r_1+r_2+r_3}$

It should be noted that, RNC periodically can send scheduling priority factor to each base station, concrete, RNC is for each base station belonging to each multithread community corresponding to user, corresponding transmission frequency is set respectively, then for each base station, respectively according to the transmission frequency arranged for this base station, the scheduling priority factor in the multithread community this user determined controlled in this base station sends to this base station.

Further, RNC can also dynamically update the transmission frequency arranged respectively for each base station, concrete, RNC is for each base station belonging to each multithread community corresponding to user, the Congestion Level SPCC of the Iub interface respectively between basis and this base station, dynamically update the transmission frequency arranged for this base station, follow-up RNC can send according to the transmission frequency after renewal the scheduling priority factor determined to this base station.If the Iub interface between RNC and base station is idle, then the transmission frequency arranged for base station can be improved, on the contrary, if the Iub interface between RNC and base station is congested, then the transmission frequency arranged for base station can be reduced.

Wherein, the Congestion Level SPCC of Iub interface can characterize with the usage rate of Iub interface, pre-set each usage rate scope, and be that each usage rate scope arranges corresponding transmission frequency respectively, when RNC needs to upgrade the transmission frequency arranged for certain base station, first can obtain the usage rate of the Iub interface between this base station, then the transmission frequency that usage rate scope belonging to this usage rate is corresponding is determined, using the transmission frequency determined as the transmission frequency arranged for this base station after upgrading.RNC can pre-set a minimum guarantee transmission frequency, such as, be set to every 100 milliseconds send once, RNC should be not less than this minimum guarantee transmission frequency for the transmission frequency that base station is arranged, that is, when Iub interface between RNC and base station is very congested, can send with this minimum guarantee transmission frequency the scheduling priority factor determined to base station.

Preferably, RNC according to the update cycle of presetting, can periodically upgrade the transmission frequency arranged for each base station.

Embodiment five:

The embodiment of the present invention five describes a kind of base station belonged to embodiment one under same inventive concept, as shown in Figure 9, comprising:

Throughput acquiring unit 91, for obtaining the downlink data throughput in multithread community that this user controls in other base stations;

Dispatching priority determining unit 92, downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations for this user of getting according to throughput acquiring unit 91 and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

Scheduling of resource unit 93, for the scheduling of resource priority determined according to dispatching priority determining unit 92, is the resource of the multithread community that base station described in this user scheduling controls.

Further, described base station also comprises:

First throughput transmitting element, for by physical connection, sends to other base stations by the downlink data throughput of user in the multithread community self controlled;

Described throughput acquiring unit 91, specifically for receiving the downlink data throughput in multithread community that other base stations send, this user controls in other base stations described.

Further, described first throughput transmitting element, specifically for according to the first transmission frequency arranged for other base stations, the downlink data throughput in multithread community user controlled in this base station sends to other base stations described.

Further, described base station also comprises:

First transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and other base stations, upgrades the first transmission frequency arranged for other base stations described.

Further, described first throughput transmitting element, specifically for sending to other base stations by the downlink data throughput of this user in each multithread community self controlled; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to other base stations.

Further, described base station also comprises:

Second throughput transmitting element, for reporting radio network controller (RNC) by the downlink data throughput of user in the multithread community self controlled;

Described throughput acquiring unit 91, specifically for receiving the downlink data throughput in multithread community that RNC sends, this user controls in other base stations.

Further, the second throughput transmitting element, specifically for according to the second transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

Further, described base station also comprises:

Second transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

Further, described second throughput transmitting element, specifically for sending to RNC by the downlink data throughput of this user in each multithread community self controlled; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to RNC.

Further, dispatching priority determining unit 92, downlink data throughput in the multithread community controlled in described base station specifically for the downlink data throughput in the multithread community that controls in other base stations according to this user of getting and this user, determines the downlink data throughput sum of this user in each multithread community of correspondence; Maximum downstream data throughput in the multithread community controlled in described base station according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

Further, described dispatching priority determining unit 92 determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweigtht}}_i$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

The embodiment of the present invention five also describes another kind of base station, as shown in Figure 10, comprising:

Receiver 101, for receiving the downlink data throughput in multithread community that this user controls in other base stations;

Processor 102, downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations for this user of receiving according to receiver 101 and this user control in described base station, determine the scheduling of resource priority in the multithread community that this user controls in described base station, and according to the scheduling of resource priority determined, be the resource of the multithread community that base station described in this user scheduling controls.

Further, described base station also comprises:

Transmitter 103, for by physical connection, sends to other base stations by the downlink data throughput of user in the multithread community self controlled;

Described receiver 101, specifically for receiving the downlink data throughput in multithread community that other base stations send, this user controls in other base stations described.

Further, described transmitter 103, specifically for according to the first transmission frequency arranged for other base stations, the downlink data throughput in multithread community user controlled in this base station sends to other base stations described.

Further, described processor 102, also for the Congestion Level SPCC of the interface between basis and other base stations, upgrades the first transmission frequency arranged for other base stations described.

Further, described transmitter 103, specifically for sending to other base stations by the downlink data throughput of this user in each multithread community self controlled; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to other base stations.

Further, described base station also comprises:

Transmitter 103, for reporting RNC by the downlink data throughput of user in the multithread community self controlled;

Described receiver 101, specifically for receiving the downlink data throughput in multithread community that RNC sends, this user controls in other base stations.

Further, transmitter 103, specifically for according to the second transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

Further, described processor 102, also for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

Further, described transmitter 103, specifically for sending to RNC by the downlink data throughput of this user in each multithread community self controlled; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to RNC.

Further, described processor 102, downlink data throughput in the multithread community controlled in described base station specifically for the downlink data throughput in the multithread community that controls in other base stations according to this user of getting and this user, determines the downlink data throughput sum of this user in each multithread community of correspondence; Maximum downstream data throughput in the multithread community controlled in described base station according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

Further, the scheduling of resource priority in the multithread community that this user controls in described base station determined by described processor 102 by following manner:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweigtht}}_i$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Embodiment six:

The embodiment of the present invention six describes a kind of RNC belonged to embodiment two under same inventive concept, as shown in figure 11, comprising:

Throughput receiving element 111, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Throughput transmitting element 112, for for each base station belonging to each multithread community corresponding to this user, the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

Further, described throughput transmitting element 111, specifically for for each base station belonging to each multithread community corresponding to this user, respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

Further, described RNC also comprises:

Transmission frequency updating block, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

The embodiment of the present invention six also describes another kind of RNC, as shown in figure 12, comprising:

Receiver 121, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Transmitter 122, for for each base station belonging to each multithread community corresponding to this user, the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

Further, described transmitter 122, specifically for for each base station belonging to each multithread community corresponding to this user, respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

Further, described RNC also comprises:

Processor 123, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

Embodiment seven:

The embodiment of the present invention seven describes a kind of base station belonged to embodiment three under same inventive concept, as shown in figure 13, comprising:

Priority factors acquiring unit 131, for obtaining the scheduling priority factor in multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence;

Dispatching priority determining unit 132, scheduling priority factor in the multithread community controlled in described base station for this user of getting according to priority factors acquiring unit 131, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

Scheduling of resource unit 133, for the scheduling of resource priority determined according to dispatching priority determining unit 132, is the resource of the multithread community that base station described in this user scheduling controls.

Further, described scheduling priority factor is the downlink data throughput sum of user in each multithread community of correspondence.

Further, described base station also comprises:

First throughput transmitting element, for sending to RNC by the downlink data throughput of user in the multithread community self controlled;

Described priority factors acquiring unit 131, specifically for receiving scheduling priority factor that RNC sends, that determine according to the downlink data throughput of this user in each multithread community of correspondence.

Further, described first throughput transmitting element, specifically for according to the first transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

Further, described base station also comprises:

First transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described first transmission frequency.

Further, described dispatching priority determining unit 132, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user of getting and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

Further, described dispatching priority determining unit 132 determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i$

$Z_i=\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Further, the ratio of the dispatching priority weight in the described scheduling priority factor multithread community that to be this user control in described base station and the downlink data throughput sum of this user in corresponding each multithread community.

Further, described base station also comprises:

Second throughput transmitting element, for sending to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput;

Described priority factors acquiring unit 131, specifically for receiving the scheduling priority factor that the dispatching priority weight in multithread community that RNC sends, that control in described base station according to this user and the downlink data throughput in each multithread community of this user in correspondence are determined.

Further, described second throughput transmitting element, specifically for according to the second transmission frequency arranged, sends to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput.

Further, described base station also comprises:

Second transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

Further, described dispatching priority determining unit 132, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user of getting and this user, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

Further, described dispatching priority determining unit 132 determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

priority _i＝R _i*Z _i

$Z_i={\mathrm{SPIweight}}_i/\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

The embodiment of the present invention seven also describes another kind of base station, as shown in figure 14, comprising:

Receiver 141, for receiving the scheduling priority factor in multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence;

Processor 142, scheduling priority factor in the multithread community controlled in described base station for this user of receiving according to receiver 141, determine the scheduling of resource priority in the multithread community that this user controls in described base station, according to the scheduling of resource priority determined, it is the resource of the multithread community that base station described in this user scheduling controls.

Further, described scheduling priority factor is the downlink data throughput sum of user in each multithread community of correspondence.

Further, described base station also comprises:

Transmitter 143, for sending to RNC by the downlink data throughput of user in the multithread community self controlled;

Described receiver 141, specifically for receiving scheduling priority factor that RNC sends, that determine according to the downlink data throughput of this user in each multithread community of correspondence.

Further, described transmitter 143, specifically for according to the first transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

Further, described processor 142, also for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described first transmission frequency.

Further, described processor 142, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

Further, the scheduling of resource priority in the multithread community that this user controls in described base station determined by described processor 142 by following manner:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i$

$Z_i=\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Further, the ratio of the dispatching priority weight in the described scheduling priority factor multithread community that to be this user control in described base station and the downlink data throughput sum of this user in corresponding each multithread community.

Further, described base station also comprises:

Transmitter 143, for sending to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput;

Described receiver 141, specifically for receiving the scheduling priority factor that the dispatching priority weight in multithread community that RNC sends, that control in described base station according to this user and the downlink data throughput in each multithread community of this user in correspondence are determined.

Further, described transmitter 143, specifically for according to the second transmission frequency arranged, sends to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput.

Further, described processor 142, also for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

Further, described processor 142, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user and this user, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

Further, the scheduling of resource priority in the multithread community that this user controls in described base station determined by described processor 142 by following manner:

priority _i＝R _i*Z _i

$Z_i={\mathrm{SPIweight}}_i/\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

Embodiment eight:

The embodiment of the present invention eight describes a kind of RNC belonged to embodiment four under same inventive concept, as shown in figure 15, comprising:

Throughput receiving element 151, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Scheduling priority factor determining unit 152, for for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station;

Scheduling priority factor transmitting element 153, the scheduling priority factor for scheduling priority factor determining unit 152 being determined sends to this base station.

Further, described scheduling priority factor transmitting element 153, specifically for according to the transmission frequency arranged for this base station, sends to this base station by the scheduling priority factor determined.

Further, described RNC also comprises:

Transmission frequency adjustment unit, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

Further, described scheduling priority factor determining unit 152, specifically for determining the downlink data throughput sum of this user in each multithread community of correspondence; By the described downlink data throughput sum determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

Further, described throughput receiving element 151, the downlink data throughput in that send respectively specifically for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community and dispatching priority weight;

Described scheduling priority factor determining unit 152, specifically for determining the ratio of the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community; By the described ratio determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

The embodiment of the present invention eight also describes another kind of RNC, as shown in figure 16, comprising:

Receiver 161, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Processor 162, for for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station

Transmitter 163, the scheduling priority factor for being determined by processor 162 sends to this base station.

Further, described transmitter 163, specifically for according to the transmission frequency arranged for this base station, sends to this base station by the scheduling priority factor determined.

Further, described processor 162, also for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

Further, described processor 162, specifically for determining the downlink data throughput sum of this user in each multithread community of correspondence; By the described downlink data throughput sum determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

Further, described receiver 161, the downlink data throughput in that send respectively specifically for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community and dispatching priority weight;

Described processor 162, specifically for determining the ratio of the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community; By the described ratio determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

Those skilled in the art should understand, embodiments of the invention can be provided as method, system or computer program.The present invention can adopt in one or more form wherein including the upper computer program implemented of computer-usable storage medium (including but not limited to magnetic disc store, CD-ROM, optical memory etc.) of computer usable program code.

The present invention describes with reference to according to the flow chart of the method for the embodiment of the present invention, equipment (system) and computer program and/or block diagram.Should understand can by the combination of the flow process in each flow process in computer program instructions realization flow figure and/or block diagram and/or square frame and flow chart and/or block diagram and/or square frame.These computer program instructions can being provided to the processor of all-purpose computer, special-purpose computer, Embedded Processor or other programmable data processing device to produce a machine, making the instruction performed by the processor of computer or other programmable data processing device produce device for realizing the function of specifying in flow chart flow process or multiple flow process and/or block diagram square frame or multiple square frame.

These computer program instructions also can be stored in can in the computer-readable memory that works in a specific way of vectoring computer or other programmable data processing device, the instruction making to be stored in this computer-readable memory produces the manufacture comprising command device, and this command device realizes the function of specifying in flow chart flow process or multiple flow process and/or block diagram square frame or multiple square frame.

These computer program instructions also can be loaded in computer or other programmable data processing device, make on computer or other programmable devices, to perform sequence of operations step to produce computer implemented process, thus the instruction performed on computer or other programmable devices is provided for the step realizing the function of specifying in flow chart flow process or multiple flow process and/or block diagram square frame or multiple square frame.

According to defining herein, computer-readable medium does not comprise the computer readable media (transitory media) of non-standing, as data-signal and the carrier wave of modulation.

Although describe the preferred embodiments of the present invention, those skilled in the art once obtain the basic creative concept of cicada, then can make other change and amendment to these embodiments.So claims are intended to be interpreted as comprising preferred embodiment and falling into all changes and the amendment of the scope of the invention.

Obviously, those skilled in the art can carry out various change and modification to the present invention and not depart from the spirit and scope of the present invention.Like this, if these amendments of the present invention and modification belong within the scope of the claims in the present invention and equivalent technologies thereof, then the present invention is also intended to comprise these change and modification.

Claims (63)

1. a resource regulating method, is characterized in that, described method comprises:

Base station belonging to multithread community corresponding to user obtains the downlink data throughput in the multithread community that this user controls in other base stations;

Downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations according to this user got and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

According to the scheduling of resource priority determined, it is the resource of the multithread community that base station described in this user scheduling controls.

2. the method for claim 1, is characterized in that, described base station obtains the downlink data throughput in the multithread community that this user controls in other base stations, specifically comprises:

Described base station receives the downlink data throughput in the multithread community that other base stations are sent by physical connection, this user controls in other base stations described.

3. method as claimed in claim 2, is characterized in that, also comprise:

Described base station is according to the first transmission frequency arranged for described other base stations, and the downlink data throughput in multithread community user controlled in this base station sends to other base stations described.

4. method as claimed in claim 3, is characterized in that, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between other base stations described, upgrades the first transmission frequency arranged for other base stations described.

5. the method for claim 1, is characterized in that, described base station obtains the downlink data throughput in the multithread community that this user controls in other base stations, specifically comprises:

Described base station receives the downlink data throughput in the multithread community that radio network controller (RNC) sends, this user controls in other base stations.

6. method as claimed in claim 5, is characterized in that, also comprise:

Described base station is according to the second transmission frequency arranged, and the downlink data throughput in multithread community user controlled in this base station reports described RNC.

7. method as claimed in claim 6, is characterized in that, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between described RNC, upgrades described second transmission frequency.

8. the method as described in claim arbitrary in claim 1 ~ 7, is characterized in that, the downlink data throughput in the multithread community that this user controls in other base stations is:

Downlink data throughput in each multithread community that this user controls in other base stations; Or

Downlink data throughput sum in each multithread community that this user controls in other base stations.

9. the method as described in claim arbitrary in claim 1 ~ 8, is characterized in that, determines the scheduling of resource priority in the multithread community that this user controls in described base station, specifically comprises:

Downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations according to this user got and this user control in described base station, determines the downlink data throughput sum of this user in each multithread community of correspondence;

Maximum downstream data throughput in the multithread community controlled in described base station according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

10. method as claimed in claim 9, is characterized in that, the scheduling of resource priority in the multithread community that this user controls in described base station is determined by following manner in described base station:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweight}}_i$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

11. 1 kinds of information interacting methods, is characterized in that, described method comprises:

Radio network controller (RNC) receives the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station;

Described RNC is for each base station belonging to each multithread community corresponding to this user, and the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

12. methods as claimed in claim 11, it is characterized in that, described RNC is for each base station belonging to each multithread community corresponding to this user, and the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station, specifically comprises:

Described RNC is for each base station belonging to each multithread community corresponding to this user, and respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

13. methods as claimed in claim 12, is characterized in that, also comprise:

Described RNC for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

14. 1 kinds of resource regulating methods, is characterized in that, described method comprises:

Base station belonging to multithread community corresponding to user obtains the scheduling priority factor in the multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence;

Scheduling priority factor in the multithread community controlled in described base station according to this user got, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

According to the scheduling of resource priority determined, it is the resource of the multithread community that base station described in this user scheduling controls.

15. methods as claimed in claim 14, is characterized in that, described scheduling priority factor is the downlink data throughput sum of user in each multithread community of correspondence.

16. methods as claimed in claim 15, is characterized in that, described base station obtains the scheduling priority factor in the multithread community that this user controls in described base station, specifically comprises:

Described base station receives scheduling priority factor that radio network controller (RNC) sends, that determine according to the downlink data throughput of this user in each multithread community of correspondence.

17. methods as claimed in claim 16, is characterized in that, also comprise:

Described base station is according to the first transmission frequency arranged, and the downlink data throughput in multithread community user controlled in this base station reports described RNC.

18. methods as claimed in claim 17, is characterized in that, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between described RNC, upgrades described first transmission frequency.

Method as described in 19. claims as arbitrary in claim 15 ~ 18, it is characterized in that, scheduling priority factor in the multithread community controlled in described base station according to this user got, determine the scheduling of resource priority in the multithread community that this user controls in described base station, specifically comprise:

Maximum downstream data throughput in the multithread community that scheduling priority factor in the multithread community controlled in described base station according to this user got and this user control in described base station and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

20. methods as claimed in claim 19, is characterized in that, the scheduling of resource priority in the multithread community that this user controls in described base station is determined by following manner in described base station:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i$

$Z_i=\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

21. methods as claimed in claim 14, it is characterized in that, the ratio of the dispatching priority weight in the described scheduling priority factor multithread community that to be this user control in described base station and the downlink data throughput sum of this user in corresponding each multithread community.

22. methods as claimed in claim 21, is characterized in that, described base station obtains the scheduling priority factor in the multithread community that this user controls in described base station, specifically comprises:

Described base station receives the scheduling priority factor that the dispatching priority weight in multithread community that radio network controller (RNC) sends, that control in described base station according to this user and the downlink data throughput in each multithread community of this user in correspondence are determined.

23. methods as claimed in claim 22, is characterized in that, also comprise:

Described base station is according to the second transmission frequency arranged, and the dispatching priority weight in multithread community user controlled in this base station and downlink data throughput report described RNC.

24. methods as claimed in claim 23, is characterized in that, also comprise:

Described base station, according to the Congestion Level SPCC of the interface between described RNC, upgrades described second transmission frequency.

25. methods as described in claim arbitrary in claim 21 ~ 24, it is characterized in that, scheduling priority factor in the multithread community controlled in described base station according to this user got, determine the scheduling of resource priority in the multithread community that this user controls in described base station, specifically comprise:

Maximum downstream data throughput in the multithread community that scheduling priority factor in the multithread community controlled in described base station according to this user got and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

26. methods as claimed in claim 25, is characterized in that, the scheduling of resource priority in the multithread community that this user controls in described base station is determined by following manner in described base station:

priority _i＝R _i*Z _i

$Z_i={\mathrm{SPIweight}}_i/\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

27. 1 kinds of information interacting methods, is characterized in that, described method comprises:

Radio network controller (RNC) receives the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station;

Described RNC is for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, and the scheduling priority factor determined is sent to this base station.

28. methods as claimed in claim 27, it is characterized in that, the scheduling priority factor determined is sent to this base station by described RNC, specifically comprises:

The scheduling priority factor determined, according to the transmission frequency arranged for this base station, is sent to this base station by described RNC.

29. methods as claimed in claim 28, is characterized in that, also comprise:

Described RNC for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

30. methods as described in claim arbitrary in claim 27 ~ 29, it is characterized in that, according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, specifically comprise:

Determine the downlink data throughput sum of this user in each multithread community of correspondence;

By the described downlink data throughput sum determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

31. methods as described in claim arbitrary in claim 27 ~ 29, it is characterized in that, receive the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station, specifically comprise:

Receive the downlink data throughput in the multithread community that each base station belonging to each multithread community corresponding to user sends respectively, this user controls in this base station and dispatching priority weight;

According to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station, specifically comprise:

Determine the ratio of the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community;

By the described ratio determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

32. 1 kinds of base stations, is characterized in that, comprising:

Throughput acquiring unit, for obtaining the downlink data throughput in multithread community that this user controls in other base stations;

Dispatching priority determining unit, downlink data throughput in the multithread community that downlink data throughput in the multithread community controlled in other base stations for this user of getting according to throughput acquiring unit and this user control in described base station, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

Scheduling of resource unit, for the scheduling of resource priority determined according to dispatching priority determining unit, is the resource of the multithread community that base station described in this user scheduling controls.

33. base stations as claimed in claim 32, it is characterized in that, described base station also comprises:

First throughput transmitting element, for by physical connection, sends to other base stations by the downlink data throughput of user in the multithread community self controlled;

Described throughput acquiring unit, specifically for receiving the downlink data throughput in multithread community that other base stations send, this user controls in other base stations described.

34. base stations as claimed in claim 33, it is characterized in that, described first throughput transmitting element, specifically for according to the first transmission frequency arranged for other base stations, the downlink data throughput in multithread community user controlled in this base station sends to other base stations described.

35. base stations as claimed in claim 34, it is characterized in that, described base station also comprises:

First transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and other base stations, upgrades the first transmission frequency arranged for other base stations described.

36. base stations as described in claim arbitrary in claim 33 ~ 35, is characterized in that, described first throughput transmitting element, specifically for the downlink data throughput of this user in each multithread community self controlled is sent to other base stations; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to other base stations.

37. base stations as claimed in claim 32, it is characterized in that, described base station also comprises:

Second throughput transmitting element, for reporting radio network controller (RNC) by the downlink data throughput of user in the multithread community self controlled;

Described throughput acquiring unit, specifically for receiving the downlink data throughput in multithread community that RNC sends, this user controls in other base stations.

38. base stations as claimed in claim 37, is characterized in that, the second throughput transmitting element, and specifically for according to the second transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

39. base stations as claimed in claim 38, it is characterized in that, described base station also comprises:

Second transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

40. base stations as described in claim arbitrary in claim 37 ~ 39, is characterized in that, described second throughput transmitting element, specifically for the downlink data throughput of this user in each multithread community self controlled is sent to RNC; Maybe the downlink data throughput sum of this user in each multithread community self controlled is sent to RNC.

41. base stations as described in claim arbitrary in claim 32 ~ 40, it is characterized in that, dispatching priority determining unit, downlink data throughput in the multithread community controlled in described base station specifically for the downlink data throughput in the multithread community that controls in other base stations according to this user of getting and this user, determines the downlink data throughput sum of this user in each multithread community of correspondence; Maximum downstream data throughput in the multithread community controlled in described base station according to the described downlink data throughput sum determined and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

42. base stations as claimed in claim 41, is characterized in that, described dispatching priority determining unit determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

${\mathrm{priority}}_i=\frac{R_i}{\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j}*{\mathrm{SPIweight}}_i$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

43. 1 kinds of radio network controllers, is characterized in that, comprising:

Throughput receiving element, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Throughput transmitting element, for for each base station belonging to each multithread community corresponding to this user, the downlink data throughput in the multithread community this user controlled in other base stations respectively sends to this base station.

44. radio network controllers as claimed in claim 43, it is characterized in that, described throughput transmitting element, specifically for for each base station belonging to each multithread community corresponding to this user, respectively according to the transmission frequency arranged for this base station, the downlink data throughput in the multithread community this user controlled in other base stations sends to this base station.

45. radio network controllers as claimed in claim 44, is characterized in that, also comprise:

Transmission frequency updating block, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

46. 1 kinds of base stations, is characterized in that, comprising:

Priority factors acquiring unit, for obtaining the scheduling priority factor in multithread community that this user controls in described base station, wherein, described scheduling priority factor determines according to the downlink data throughput of this user in each multithread community of correspondence;

Dispatching priority determining unit, the scheduling priority factor in the multithread community controlled in described base station for this user of getting according to priority factors acquiring unit, determines the scheduling of resource priority in the multithread community that this user controls in described base station;

Scheduling of resource unit, for the scheduling of resource priority determined according to dispatching priority determining unit, is the resource of the multithread community that base station described in this user scheduling controls.

47. base stations as claimed in claim 46, is characterized in that, described scheduling priority factor is the downlink data throughput sum of user in each multithread community of correspondence.

48. base stations as claimed in claim 47, it is characterized in that, described base station also comprises:

First throughput transmitting element, for sending to radio network controller (RNC) by the downlink data throughput of user in the multithread community self controlled;

Described priority factors acquiring unit, specifically for receiving scheduling priority factor that RNC sends, that determine according to the downlink data throughput of this user in each multithread community of correspondence.

49. base stations as claimed in claim 48, is characterized in that, described first throughput transmitting element, and specifically for according to the first transmission frequency arranged, the downlink data throughput in multithread community user controlled in this base station reports RNC.

50. base stations as claimed in claim 49, is characterized in that, also comprise:

First transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described first transmission frequency.

51. base stations as described in claim arbitrary in claim 47 ~ 50, it is characterized in that, described dispatching priority determining unit, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user of getting and this user and dispatching priority weight, determine the scheduling of resource priority in the multithread community that this user controls in described base station.

52. base stations as claimed in claim 51, is characterized in that, described dispatching priority determining unit determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

${\mathrm{priority}}_i=\frac{R_i}{Z_i}*{\mathrm{SPIweight}}_i$

$Z_i=\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

53. base stations as claimed in claim 46, it is characterized in that, the ratio of the dispatching priority weight in the described scheduling priority factor multithread community that to be this user control in described base station and the downlink data throughput sum of this user in corresponding each multithread community.

54. base stations as claimed in claim 53, it is characterized in that, described base station also comprises:

Second throughput transmitting element, for sending to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput;

Described priority factors acquiring unit, specifically for receiving the scheduling priority factor that the dispatching priority weight in multithread community that RNC sends, that control in described base station according to this user and the downlink data throughput in each multithread community of this user in correspondence are determined.

55. base stations as claimed in claim 54, it is characterized in that, described second throughput transmitting element, specifically for according to the second transmission frequency arranged, sends to RNC by the dispatching priority weight of user in the multithread community self controlled and downlink data throughput.

56. base stations as claimed in claim 55, is characterized in that, also comprise:

Second transmission frequency updating block, for the Congestion Level SPCC of the interface between basis and described RNC, upgrades described second transmission frequency.

57. base stations as described in claim arbitrary in claim 53 ~ 56, it is characterized in that, described dispatching priority determining unit, maximum downstream data throughput in the multithread community controlled in described base station specifically for the scheduling priority factor in the multithread community that controls in described base station according to this user of getting and this user, determines the scheduling of resource priority in the multithread community that this user controls in described base station.

58. base stations as claimed in claim 57, is characterized in that, described dispatching priority determining unit determines the scheduling of resource priority in the multithread community that this user controls in described base station by following manner:

priority _i＝R _i*Z _i

$Z_i={\mathrm{SPIweight}}_i/\underset{j=1}{\overset{n}{\mathrm{\Σ}}}{r}_j$

Wherein, priority _ifor the scheduling of resource priority in the multithread cell i that this user controls in described base station;

R _ifor the maximum downstream data throughput in the multithread cell i that this user controls in described base station;

Z _ifor the scheduling priority factor in the multithread cell i that this user controls in described base station;

SPIweight _ifor the dispatching priority weight in the multithread cell i that this user controls in described base station;

R _jfor the downlink data throughput of this user in the multithread community j of correspondence;

N is the quantity of multithread community corresponding to this user.

59. 1 kinds of radio network controllers, is characterized in that, comprising:

Throughput receiving element, the downlink data throughput in that send respectively for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community;

Scheduling priority factor determining unit, for for each base station belonging to each multithread community corresponding to this user, perform following operation respectively: according to the downlink data throughput of this user in each multithread community of correspondence, determine the scheduling priority factor in the multithread community that this user controls in this base station;

Scheduling priority factor transmitting element, the scheduling priority factor for scheduling priority factor determining unit being determined sends to this base station.

60. radio network controllers as claimed in claim 59, is characterized in that the scheduling priority factor determined, specifically for according to the transmission frequency arranged for this base station, is sent to this base station by described scheduling priority factor transmitting element.

61. radio network controllers as claimed in claim 60, is characterized in that, also comprise:

Transmission frequency adjustment unit, for for each base station belonging to each multithread community corresponding to this user, respectively according to and this base station between the Congestion Level SPCC of interface, upgrade the transmission frequency arranged for this base station.

62. radio network controllers as described in claim arbitrary in claim 59 ~ 61, is characterized in that, described scheduling priority factor determining unit, specifically for determining the downlink data throughput sum of this user in each multithread community of correspondence; By the described downlink data throughput sum determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.

63. radio network controllers as described in claim arbitrary in claim 59 ~ 61, it is characterized in that, described throughput receiving element, the downlink data throughput in that send respectively specifically for each base station received belonging to each multithread community corresponding to user, that this user controls in this base station multithread community and dispatching priority weight;

Described scheduling priority factor determining unit, specifically for determining the ratio of the dispatching priority weight in the multithread community that this user controls in this base station and the downlink data throughput sum of this user in corresponding each multithread community; By the described ratio determined, confirm as the scheduling priority factor in the multithread community that this user controls in this base station.