CN104378829A - Method for implementing channel allocating and scheduling based on service types and equipment thereof - Google Patents

Abstract

The invention discloses a method for dynamically controlling channel allocation and scheduling strategies on the base station side based on satisfying user service experience, comprising the following steps: A. confirming the service type of the user service according to the characteristics of the user service; B. according to The service type allocates a corresponding type of control channel resource to the user service; c. using a corresponding type of scheduling method for the user service according to the service type. The invention also discloses a base station equipment using the method.

Description

A method and device for implementing channel allocation and scheduling based on service type

technical field

The present invention relates to the field of communications, in particular to a method and device for allocating control channels and implementing scheduling based on user experience.

Background technique

As we all know, this is an era of mobile data explosion, and various types of mobile terminals (for example, smart phones, touch panel computers) all require persistent online services of mobile networks, especially for LTE networks. For Android devices alone, 850,000 new devices are activated in the market every day, and one in every 35 is downloading an app. Many of the most popular apps are constantly connected to the network to check for updates. Many apps (such as twitter, msn, Gtalk) allow a large number of users to use network resources at the same time. Since all these small downloads require network resources, it may quickly lead to the deterioration of network quality. For this, the industry calls it Signaling storm. Many operators around the world are already feeling the impact of smart devices. In Japan in January 2012, 2.5 million users were unable to use voice calling services due to signaling storms.

Although the existing technology provides some technical solutions to the above-mentioned signaling storm problem, there are still several defects as follows: there is no detailed division of service types based on user experience; no efficient control channel resource management is involved; no user experience-based Efficient packet scheduling; no base station capacity management based on user experience; the present invention solves these defects and provides a more efficient and adaptive solution to meet the user experience of mobile terminals. The above problems will be solved in the present invention, so as to provide a more efficient and adaptive solution to meet the user experience of various types of services.

Contents of the invention

Due to the characteristics of wireless network services, such as Gtalk, twitter and app automatic update, most data sessions are very short and contain little payload data. Analysis shows that 80% of the usage duration is less than 10 seconds, and 60% of The amount of data required by a session is less than 1K bits. If there are a large number of such users in the network, too many air interface resources will be occupied in the uplink and downlink channels, and this will cause almost no remaining resources to be reserved. If the traffic channel is used to transmit useful data, the capacity and user experience will be greatly reduced. In this solution, we propose a new method to avoid this problem in the LTE system as well as in TDD and FDD. The invention effectively prevents the occurrence of signaling storms and satisfies the needs of user experience in various wireless network services.

The invention discloses a method for dynamically controlling channel allocation and scheduling strategies on the base station side, comprising the following steps: A. confirming the service type of the user service according to the characteristics of the user service; B. determining the service type of the user service according to the service type Allocating corresponding types of control channel resources to the user service; C. Using a corresponding type of scheduling method for the user service according to the service type.

In particular, the service type of the user service is the instant degree or user experience of the user service, and in the step A: classify the service type of the user service, and the classified type includes at least instant service , one of semi-immediate service and non-perceived service; in the step B: the control channel resources corresponding to real-time service, semi-immediate service and non-perceived service are allocated respectively as real-time service control channel, semi-real-time service control channel and Non-perceptual service control channel, control channel resources include P-CQI, A-CQI, SR, SOUNDING.

Specifically, in the step B: mapping multiple semi-immediate service control channels for the immediate service control channel, and mapping multiple non-perceptual service control channels for the semi-immediate service control channel.

In particular, the scheduling method used in the step C is: based on the confirmation of the user service type, the user scheduling time interval is set, and after the previous round of scheduling is completed, the next round of scheduling is performed after a period of time interval; The round schedule is set to one or more schedules, or set to a group of schedules that send all the current data to be transmitted; the scheduling time interval of the instant service is less than the scheduling time interval of the semi-instant service, and the semi-instant service The scheduling time interval of the instant service is smaller than the scheduling time interval of the non-aware service. The method can effectively save the overhead of control signaling and avoid network congestion.

Particularly, before described step A, also comprise the step: judge whether the quantity of connected users reaches connection number threshold value; When the user quantity of connection is greater than described connection number threshold value, then the initial business type of the user of all connections is regarded as semi-instantaneous business, and execute the steps A, B, and C; when the number of connected users is less than the connection number threshold, all connected user service types are regarded as instant services, and the steps B, C are executed.

In particular, step A further includes: confirming the service type of the user service used by the connected user at a fixed period. Periodically confirming the service type of the user service can cope with the situation that the user service type is constantly changing, so that the base station can dynamically control channel allocation and adjust the scheduling strategy more effectively.

In particular, the period is 1 second.

Specifically, in the step B, 4 semi-real-time service control channels are mapped to the real-time service control channel, and 2 non-perceptual service control channels are mapped to the semi-real-time service control channel.

In particular, the periodic channel quality indication period of the real-time service control channel is 20ms, the detection signaling period is 20ms, and the scheduling request period is 10ms; the periodic channel quality indication period of the semi-real-time service control channel is 80ms, and the detection signaling period is 20ms. The signaling period is 80ms, the scheduling request period is 40ms; the periodic channel quality indication period of the non-perceptual service control channel is 160ms, the probing signal period is 160ms, and the scheduling request period is 80ms.

In particular, the scheduling interval of the real-time service is schedulable every millisecond, the scheduling interval of the semi-instant service is 80ms, and the scheduling interval of the non-aware service is 160ms.

Particularly, in the step A, when the user service contains at least any of the following situations, the user service is regarded as an instant service: the user service has GRB data bearing; the user service average traffic exceeds 1Mbit/s ; The data waiting to be transmitted in the user data cache exceeds 500Kbits; the average data burst interval is less than 100ms.

Particularly, in the step A, when the user service satisfies all of the following conditions, the user service is regarded as a semi-instant service: the user service has only non-GRB data bearing the user service average flow rate greater than 10Kbit/s and less than 100Kbit/s s; The signal-to-interference-plus-noise ratio of the user is greater than 2dB; the data waiting to be transmitted in the user data cache is greater than 10Kbits and less than 50Kbits; the average data burst interval is greater than 100ms and less than 5s.

Specifically, in the step A, when the user service satisfies all of the following conditions, the user service is regarded as a non-perceptual service: the user service only has non-GRB data bearer; the average flow rate of the user service is less than 10Kbit/s; the user service The signal-to-interference plus noise ratio is greater than 2dB; the data waiting to be transmitted in the user data cache is less than 10Kbits; the average data burst interval is greater than 5s.

The present invention also discloses a base station device, comprising: a service type determination unit, which is used to confirm the service type of the user service according to the characteristics of the user service; a channel allocation unit, which is used to assign the user service type according to the service type The service allocates the corresponding type of control channel resources; the scheduling implementation unit is configured to use the corresponding type of scheduling method for the user service according to the service type.

In particular, the service type determination unit confirms the service type of the user service as one of immediate service, semi-immediate service and non-aware service; The control channel resources to which services are assigned are real-time service control channels, semi-real-time service control channels, and non-perceptual service control channels, wherein the allocating channel unit maps multiple semi-real-time service control channels to the real-time service control channel, Mapping a plurality of non-aware service control channels for the semi-immediate service control channel; and, the scheduling time interval of the real-time service by the scheduling implementation unit is less than the scheduling time interval of the semi-real-time service, and the scheduling of the semi-real-time service The time interval is smaller than the scheduling time interval of the non-aware service.

Description of drawings

Through the following detailed description of the embodiments shown in conjunction with the drawings, the above-mentioned and other features of the present invention will be more obvious, and the same or similar symbols in the drawings of the present invention represent the same or similar steps;

Figure 1 shows a flow chart of a method for implementing control channel allocation and packet scheduling strategies based on user service types at the base station side;

Figure 2 shows a block diagram of a device that implements control channel allocation and packet scheduling strategies based on user traffic types;

Figure 3 shows a mapping relationship between different control channels; and

FIG. 4 shows an embodiment of searching for control channel resources in the mapping relationship diagram.

Detailed ways

In the following detailed description of the preferred embodiment, reference is made to the accompanying drawings which form a part hereof. The accompanying drawings show, by way of example, specific embodiments in which the invention can be practiced. The illustrated embodiments are not intended to be exhaustive of all embodiments in accordance with the invention. It should be noted that although the steps of the relevant methods in the present invention are described in a specific order in the accompanying drawings, this does not require or imply that these operations must be performed in this specific order, or that all shown operations must be performed to achieve the desired result. As a result, instead, the steps described herein may be performed in a different order or performed concurrently and in parallel. Additionally or alternatively, certain steps may be omitted, multiple steps may be combined into one step for execution, and/or one step may be decomposed into multiple steps for execution.

Figure 1 shows a flow chart of a method for implementing control channel allocation and packet scheduling strategies based on user traffic types at the base station side; Figure 2 shows a device for implementing control channel allocation and packet scheduling strategies based on user traffic types The module schematic diagram; The method and steps for solving the above technical problems will be described in detail below in conjunction with the flow chart in the accompanying drawing 1 and the module schematic diagram in the accompanying drawing 2.

Accompanying drawing 2 shows a kind of module unit of base station equipment implementing control channel allocation and packet scheduling strategy based on user service type according to an embodiment of the present invention, which includes:

Service quantity confirmation unit 202, which is used to confirm the number of current RRC (radio resource control) connected users; service type determination unit 204, which is used to confirm the service type of user services according to service characteristics; allocation control channel unit 206, which is used for Allocating a corresponding type of control channel resource to the user service according to the service type; a scheduling implementation unit 208, configured to use a corresponding type of scheduling method for the user service according to the service type.

As shown in FIG. 1 , in step 102, the service quantity confirmation unit 202 confirms the quantity of connected users in the current radio resource control.

Specifically, the number of services confirming unit 202 confirms the number of users currently connected, and the threshold of the number of connections can be preset according to the channel capacity of the cell. The threshold of the number of connections indicates the maximum number of real-time services that the cell can carry at the same time. If the number of user services exceeds the threshold of the number of connections, the current services of all users cannot be implemented to meet the standards of instant services.

Wherein, the instant service refers to a service that requires high data traffic or frequently updated service data to satisfy user experience, for example, online video service, voice chat service, online game service, downloading and uploading files, and the like. Users are usually extremely sensitive to the data acquisition speed of this type of business, and any delay in data acquisition will affect user experience.

The service number confirmation unit 202 confirms whether the number of currently connected users exceeds the set connection number threshold.

When the number of connected users does not exceed the threshold of the number of connections, step 110 is executed, and each currently connected user service is regarded as an instant service, that is, all user services can be implemented according to the instant service standard.

When the number of connected users exceeds the connection number threshold, step 104 is performed to confirm the specific service type of the user service according to the characteristics of the user service. And it should be noted that: when the number of connected users exceeds the threshold of the number of connections, all user services need to perform step 104, including user services that were previously considered instant services because the number of user connections was less than the threshold of the number of connections.

In a preferred embodiment, when the number of connected users exceeds the connection number threshold, the initial service type for each user is regarded as a semi-instant service.

Wherein, the semi-real-time service refers to a service that only needs medium data traffic or updates service data less frequently and can satisfy user experience, for example, surfing the Internet, twitter, IM (voice message and text message) and so on. Users are usually sensitive to the speed of data acquisition for this type of business, and a slight delay in data acquisition will not affect user experience.

In step 110, regard the currently connected user service as an instant service, and proceed to step 106 to allocate corresponding types of control channel resources to the user service according to the service type.

In step 104, the service type determining unit 204 determines the service type of the user service according to the characteristics of the user service.

Specifically, the present invention divides user services into three types according to the real-time degree of user services according to the characteristics of user services, namely: instant services, semi-instant services and non-aware services. The service type determining unit 204 confirms the service type of the user service as one of an instant service, a semi-instant service and a non-aware service. It should be pointed out that the present invention does not limit the number of classifications of service types, and user services can also be divided into two categories, four categories or more according to the strength of the instant degree; The importance, urgency, waiting time, etc. of user services, and other user service characteristics are used to classify user types.

Among them, the real-time service and the semi-real-time service have been mentioned above, and will not be repeated here. Non-aware services refer to services that only require low data traffic or do not need to update business data immediately to meet user experience, for example, push services (advertising, news, weather), application updates, etc. The acquisition of data for such services is usually not perceived by users, or the delay in acquiring service data does not affect user experience.

In one embodiment, the user service contains at least any of the following situations, and the user service is regarded as an instant service:

There is GRB data bearer in the user service;

The user business requires high traffic. Preferably, a first traffic threshold can be set. When the average traffic of the user business exceeds the first traffic threshold, it is considered that the user business needs high traffic. In a specific embodiment, The first traffic threshold is 1Mbit/s;

The data waiting to be transmitted in the user data cache exceeds a certain amount of data. Preferably, a first cache volume threshold can be set. In a specific embodiment, the first cache volume threshold is 500Kbits;

The average data burst interval is less than a certain time interval. Preferably, a first interval threshold may be set. In a specific embodiment, the first interval threshold is 100 ms.

When the user service satisfies all of the following conditions, the user service is regarded as a semi-instant service:

The user service only bears non-GRB data;

The average flow of the user service is within a lower average flow range, and in a specific embodiment, the average flow range is greater than 10Kbit/s and less than 100Kbit/s;

The user's signal-to-interference-plus-noise ratio is greater than 2dB;

The amount of data waiting to be transmitted in the user data cache is within a range. In a specific embodiment, the range of the amount of data to be transmitted is greater than 10Kbits and less than 50Kbits;

The average data burst interval is within a limited time interval range, and in a specific embodiment, the time interval range is greater than 100ms and less than 5s.

When the user service satisfies all of the following conditions, the user service is regarded as a non-aware service:

The user service only bears non-GRB data;

The user service has a low flow rate. Preferably, a second flow threshold can be set. When the average flow rate of the user service is lower than the second flow threshold, it is considered that the user service has a low flow rate. In a specific embodiment , the second traffic threshold is 10Kbit/s;

The user's signal-to-interference-plus-noise ratio is greater than 2dB;

The data waiting to be transmitted in the user data cache is lower than a certain amount of data. Preferably, a second cache volume threshold can be set. In a specific embodiment, the second cache volume threshold is 10Kbits;

The average data burst interval is greater than a certain time interval. Preferably, a second interval threshold may be set. In a specific embodiment, the second interval threshold is 5s.

In one embodiment, the service type determining unit 204 confirms the service type of the user service used by the connected user at a fixed period, preferably, the period is 1 second. Periodically confirming the service type of the user service can cope with the situation that the user service type is constantly changing, so that the base station can dynamically control channel allocation and adjust the scheduling strategy more effectively.

After the user type of the user service is confirmed, step 106 is executed to allocate different control channels for different user services.

In step 106, the allocating control channel unit 206 receives the user service type confirmation information of the service type confirmation unit 204, and allocates corresponding control channels for real-time services, semi-real-time services, and non-aware services according to the confirmed service types. Channel resources, the channel control resources are real-time service control channels, semi-real-time service control channels, and non-perceptual service control channels, wherein the channel allocation unit 206 maps multiple semi-real-time service control channels for the real-time service control channels, which is semi-real-time service control channels The immediate service control channel maps multiple non-aware service control channels.

Specifically, as shown in Figure 3, the control channel is divided into unified resource blocks, each resource block corresponds to a control channel, each row of resource blocks corresponds to a set of configured control channels, and each set of configurations corresponds to a service type of user business. If a user's service type is an instant service, the user should be allocated to the instant service resource block in the left area, similarly, if a user's service type is a semi-instant service, the user should be allocated to the middle area In the semi-immediate service resource block, if the service type of a user is a non-aware service, the user should be allocated to the non-aware service resource block in the right area.

In an embodiment, one resource block of the real-time service in the left region can be mapped to four resource blocks of the semi-immediate service in the middle region, which means that one control channel of the real-time service can support four users under the semi-real-time service. Similarly, a semi-instant service resource block in the middle area can be mapped to two non-aware service resource blocks in the right area, which means that a semi-instant service control channel can support two non-aware service users.

Based on the above mapping relationship, Table 1 shows a preferred control channel configuration:

Table 1

It should be noted that the number of mappings can be arbitrary. It can be that one control channel (resource block) of an instant service maps two, three or more control channels (resource blocks) of a semi-immediate service, and one semi-immediate service The control channel (resource block) of the service is mapped with three, four or more control channels (resource block) of the non-aware service. However, the control channels (resource blocks) of services with high requirements on control channel configuration can only be mapped to a plurality of control channels (resource blocks) of services with low requirements on control channel configuration. A plurality of control channels (resource blocks) of services with a low degree of immediacy are mapped to a control channel (resource block) of the service of the above-mentioned service. In addition, the control channel configuration parameters change correspondingly with the change of the mapping quantity. For example, if the periodic channel quality indication period (P-CQIPeriod) in the control channel configuration of the instant service is 20ms, when a control channel of the instant service is mapped For four control channels of semi-instant services, the periodic channel quality indication period (P-CQIPeriod) in the configuration of each control channel of semi-instant services is 80ms. control channel, the periodic channel quality indication period (P-CQIPeriod) in the control channel configuration of each semi-instant service is 60ms.

When the control channel (resource block) of the service with high requirement on control channel configuration is occupied, the corresponding control channel (resource block) of the service with low requirement on control channel configuration is also occupied. In this embodiment, as shown in Figure 3, when a control channel (resource block) of a high-immediacy service is occupied, a corresponding low-immediacy control channel (resource block) having a mapping relationship with it is also occupied . For example, when the resource block index 1 is occupied in the control channel of the immediate service, the resource block indexes 1-4 in the control channel of the semi-immediate service and the resource block indexes 1-8 in the control channel of the non-perceptual service are also occupied. When the resource block index 2 in the control channel of the semi-immediate service is occupied, the corresponding resource block indexes 3 and 4 in the control channel of the non-perceptual service are also occupied.

The control channel corresponding to the idle resource block is an available idle control channel. When the allocation control channel unit 206 allocates the corresponding control channel resource for the user service according to the confirmed service type, the size of the index number in FIG. 3 Search for the free resource block from top to bottom. When other resource blocks that have a mapping relationship with the found resource block are not occupied, the found resource block is an available resource block, and the base station passes through the resource block according to the found resource block. Trigger RRC (Radio Resource Control) to configure user services; when other resource blocks that have a mapping relationship with the found resource block are occupied, continue to search downwards.

As shown in FIG. 4, gray resource blocks represent resource blocks that have been occupied. If the service type of the current user service is confirmed as a non-perceptual service, the channel control unit 206 will list the non-perceptual service from small to large in the column of non-perceptual service. The idle resource blocks are searched sequentially. According to this method, it can be found that the resource block 6 in the non-aware service is idle, so the control channel configuration corresponding to the resource block 6 is allocated to the user service. If the service type of current user service is confirmed as semi-instant service, channel control unit 206 can search idle resource block by index number from small to large order in the column of semi-instant service, after searching, find that there is mapping with semi-instant service resource block 1 The non-aware service resource block 1-2 related to the relationship is occupied, the resource block 2 in the semi-immediate service is occupied, and the non-aware service resource block 5 with a mapping relationship with the semi-immediate service resource block 3 is occupied, so the semi-instant service Resource blocks 1-3 cannot be used, but only resource block 4 in the semi-instant service can be used.

In step 108, the scheduling implementation unit 208 implements a corresponding type of scheduling method according to the service type of the user service.

Specifically, different scheduling time intervals are used for different business types according to the needs of the business type. In this embodiment, the scheduling time interval of the instant service is less than the scheduling time interval of the semi-instant service, The scheduling time interval of is less than the scheduling time interval of the non-aware service. In the real-time business, a larger data volume or a higher average data group interval is required, so more frequent implementation scheduling is required, but for non-aware services, a larger data volume or a higher average data group interval is not required, so it can be Set a lower scheduling interval.

For example, when the interval is set to 100ms, if scheduling signaling is sent to the user service at TTI (Transmission Time Interval) n, then from n+1 to n+99, the user service is no longer scheduled (removed from the pre-scheduled state The user), when TTIn+100, and the user service has cached data to be sent, the user service starts to be added to the pre-scheduling again until the scheduling signaling is sent to the user. This process ensures that there is at least 100 ms of time for encapsulating user data, so the overhead of control signaling is saved. Table 2 shows a preferred embodiment of the scheduling time interval, in this example the scheduling interval of instant service is every TTI i.e. 1ms, the scheduling interval of semi-instant service is 80ms, and the scheduling interval of non-aware service is 160ms, which means that as long as the real-time business has data transmission requirements, the data of the real-time business will be scheduled within each transmission time interval.

When the user traffic is semi-instantaneous traffic or non-aware traffic, the scheduling implementation unit 206 will force these user traffic to enter the frequency diversity scheduling mode (frequencydjversescheduling), which means that these user traffic do not have A-CQI (A- channel quality indicator) signal requirements.

Table 2

instant business semi-instant service non-aware business scheduling interval per TTI 80ms 160ms

Herein, the methods disclosed herein are described with reference to the accompanying drawings. However, it should be understood that the sequence of steps shown in the drawings and described in the specification is only illustrative, and that these method steps and/or actions may be performed in a different order without departing from the scope of the claims. They are limited to the specific order shown in the drawings and described in the specification.

The above description of the present disclosure is provided to enable any person of ordinary skill in the art to make or use the present invention. Various modifications to the present disclosure will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other modifications without departing from the spirit and scope of the invention. Thus, the invention is not to be limited to the examples and designs described herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (15)

1. base station side dynamically control channel distribute and the method for scheduling strategy, comprise the steps:

A. the type of service of described customer service is confirmed according to the feature of customer service;

B. according to described type of service, described customer service is distributed to the control channel resource of corresponding types;

C. according to described type of service, described customer service is used to the scheduling mode of corresponding types.

2. method according to claim 1, is characterized in that, the type of service of described customer service is instant degree or the Consumer's Experience of described customer service,

In described steps A:

The described type of service of described customer service classified, the type of described classification at least comprises demand service, half demand service and non-perception service;

In described step B:

The described control channel resource of distributing correspondence for demand service, half demand service and non-perception service is respectively demand service control channel, half demand service control channel and non-perception service control channel, control channel resource comprises P-CQI, A-CQI, SR, SOUNDING.

3. method according to claim 2, is characterized in that: in described step B:

For described demand service control channel maps multiple half demand service control channel, for described half demand service control channel maps multiple non-perception service control channel.

4. method according to claim 3, is characterized in that, in described step C use described scheduling mode to be:

Based on the confirmation of customer service type, the user scheduling time interval is set, after previous round has been dispatched, behind a period of time interval, carries out next round scheduling again;

Each is taken turns scheduling and is set as that one or many is dispatched, or is set as the group scheduling that current data to be transmitted all sent;

The scheduling time inter of described demand service is less than the scheduling time inter of described half demand service, and the scheduling time inter of described half demand service is less than the scheduling time inter of described non-perception service.

5. want the method described in art 4 according to right, it is characterized in that, before described steps A, also comprise step:

Judge whether the quantity connecting user reaches linking number threshold value;

When the number of users connected is greater than described linking number threshold value, then user's initial service type of all connections is considered as half demand service, and performs described steps A, B, C;

When the number of users connected is less than described linking number threshold value, then the customer service type of all connections is considered as demand service, and performs described step B, C.

6. method according to claim 5, is characterized in that, steps A also comprises: confirm by the type of service of fixing cycle to the customer service that the user connected uses.

7. method according to claim 6, is characterized in that, the described cycle is 1 second.

8. method according to claim 6, is characterized in that: in described step B, for described demand service control channel maps 4 half demand service control channels, for described half demand service control channel maps 2 non-perception service control channels.

9. method according to claim 8, is characterized in that:

The periodic channel quality instruction cycle of described demand service control channel is 20ms, and detection signaling period is 20ms, and the dispatch request cycle is 10ms;

The periodic channel quality instruction cycle of described half demand service control channel is 80ms, and detection Jin of letter is 80ms in cycle, and the dispatch request cycle is 40ms;

The periodic channel quality instruction cycle of described non-perception service control channel is 160ms, and detection signaling period is 160ms, and the dispatch request cycle is 80ms.

10. method according to claim 4, is characterized in that, the scheduling time of described demand service is every millisecond of equal schedulable, and the scheduling time inter of described half demand service is 80ms, and the scheduling time inter of described non-perception service is 160ms.

11. methods according to claim 6, is characterized in that, in described steps A, when described customer service containing, for example under any one situation at least, using this customer service as demand service:

GRB Deta bearer is had in this customer service;

This customer service average discharge is more than 1Mbit/s;

In user data cache etc. data to be transmitted more than 500Kbits;

Average data burst interval is less than 100ms.

12. methods according to claim 6, is characterized in that, in described steps A, when described customer service meets following all situations, using this customer service as half demand service:

This customer service only has non-GRB Deta bearer;

This customer service average discharge is greater than 10Kbit/s and is less than 100Kbit/s;

The Signal to Interference plus Noise Ratio of user is greater than 2dB;

User data cache awaiting transmission data are greater than 10Kbits and are less than 50Kbits;

Average data burst interval is greater than 100ms and is less than 5s.

13. methods according to claim 6, is characterized in that, in described steps A, when described customer service meets following all situations, using this customer service as non-perception service:

This customer service only has non-GRB Deta bearer;

This customer service average discharge is less than 10Kbit/s;

The Signal to Interference plus Noise Ratio of user is greater than 2dB;

User data cache awaiting transmission data are less than 10Kbits;

Average data burst interval is greater than 5s.

14. 1 kinds of base station equipments, comprising:

Type of service determining unit, it is for confirming the type of service of described customer service according to the feature of customer service;

Allocated channel unit, it is for distributing the control channel resource of corresponding types to described customer service according to described type of service;

Scheduling implementation unit, it is for using the scheduling mode of corresponding types to described customer service according to described type of service.

15. base station equipments according to claim 14, is characterized in that,

The described type of service of described customer service is confirmed as in demand service, half demand service and non-perception service by described type of service determining unit;

Described allocated channel unit is demand service, to be assigned with corresponding described control channel resource be respectively demand service control channel, half demand service control channel and non-perception service control channel for half demand service and non-perception service; wherein; described allocated channel unit is that demand service control channel maps multiple half demand service control channel, is that half demand service control channel maps multiple non-perception service control channel;

Further, the scheduling time inter of described scheduling implementation unit to described demand service is less than the scheduling time inter of described half demand service, the scheduling time inter of described half demand service is less than to the scheduling time inter of described non-perception service.