SE527220E - Downlink speed scheduling method and scheduling device - Google Patents

Description

Technical area The present invention relates to the field of data communication, and more particularly to a method and scheduler (scheduler) for scheduling downlink speeds for high speed services in CDMA systems.

Background of the invention With the relentless expansion of wireless services and the rapid development of Internet services, a simple voice service has not been able to meet the needs of users. Many users hope that mobile communication systems will be able to provide most services available in existing communication networks (including ISDN, ADSL). Therefore, data services represented by multimedia services will occupy a dominant position in the new generation of mobile communication systems. It is required that the system could provide more powerful support for data services, and services where data and speech are combined. Utilizing wireless resources sensibly and efficiently in accordance with the distinctive features of data services is a key to achieving this goal.

When a base station needs to send a number of data to a remote user, scheduling the speed assigned to the users is an important process for sensible and efficient use of the wireless resources. An article "Down-Link Scheduling in CDMA Data Networks" suggests that if a base station allocates available system resources to only one user when scheduling, the utilization of the downlink channel can be maximized. However, the scheduling method is excessively skewed in favor of the user having better channel conditions, causing longer time delays for the user data having relatively poorer channel conditions, which is unacceptable to most users due to the extreme injustice. Therefore, a good speed scheduling method should both improve the utilization of wireless resources and ensure fairness between the users of the system.

U.S. Patent No. 6,229,795B1, "System for Allocating Resources in a Communication System", provides a scheduling method that considers both resource utilization and user justice. Assuming that an instantaneous speed assigned by a base station to a user is R, and an average speed is C, the base station assigns a smaller weight to the user if R> C; if R <C assigns the base station a greater weight to the user, and the user weight can accumulate. The principle of base station scheduling is that the smaller the user's weight, the higher the user's priority, and vice versa. However, this speed scheduling method requires the base station to assign speed only in accordance with the user's channel conditions. The user with good channel conditions is assigned a higher speed, and the user with bad channel conditions is assigned a lower speed. In reality, however, users with poor channel conditions can also be assigned higher speeds as more resources may become available to the system. Therefore, system resources can be used more efficiently when scheduling speed as long as both the user's wireless conditions and the system's available resources are taken into account.

As the system schedules the user's speed, the smoothness of the scheduling is a non-negligible factor. The so-called scheduling smoothness means that as the priorities of some users increase, the priorities of other users in the system should not decrease rapidly. In other words, increasing and decreasing users' priorities should be a smooth process.

It should be noted that the existing speed scheduling method cannot take into account users' wireless conditions, available system resources and scheduling smoothness, which should be considered and improved.

Summary of the invention An object of the present invention is to provide a method for scheduling downlink speed in communication networks.

A further object of the present invention is to provide a device for scheduling downlink speed in communication networks.

To achieve the objects of the present invention, the present invention provides the following technical solutions: A downlink rate scheduling method of the present invention comprises the following steps: a. Collecting and obtaining information on maximum scheduling resources available for a system and data service requirement information from scheduling users; b. calculate scheduling measures for scheduling users, where the scheduling measures include short-term scheduling measures, long-term scheduling measures and normalized long-term scheduling measures; c. create a scheduling user queue in accordance with scheduling criteria; d. allocate speed and power according to the scheduling user queue and scheduling resources available in the system; e. remove the user who has received the resources from the scheduling user queue, and send the assignment result to a selector and at least one channel unit; and f. end a scheduling cycle and wait for the scheduling of the next cycle according to the above steps.

The above step c, where a scheduling user queue is created, further comprises the following steps: cl. create an active scheduling user queue; c2. create an inactive scheduling user queue; c3. check if the long-term scheduling measure for an active scheduling user is greater than a fixed threshold constant TI; c4. check if the difference between the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user is greater than a fixed threshold constant T2; c5. inserting the inactive scheduling user in front of the active scheduling user and removing the inactive user from the inactive scheduling user queue; and c6. check whether all active scheduling users have been examined, and, if so, end the procedure, or, if not, repeat steps c1 to c6 until all active scheduling users have been examined.

In the above step c3, the next step c4 is performed sequentially if the long-term scheduling measure of an active scheduling user is larger than the fixed threshold constant T1; otherwise step c6 is performed directly.

In the above step c4, the next step c5 is performed sequentially if the difference between the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user is greater than the fixed threshold constant T2; otherwise step c6 is performed directly.

The downlink rate scheduling method of the present invention further comprises the following steps after step e: checking whether any scheduling resources available to the system or scheduling queue are empty; and if this is false, return to step d, or, if true, first update the scheduling measures for scheduling users and then perform step f.

The procedure for updating the scheduling measures for scheduling users further comprises the following steps: el. target target speeds scheduling users, where the target speed may be a request rate for the most recent packet call, or the maximum value or average of the most recent scheduling speeds for scheduling users; e2. update the short-term scheduling measure for scheduling users; e3. update the long-term scheduling measure for scheduling users; and e4. update the normalized long-term scheduling measure for scheduling users.

The present invention provides a downlink rate scheduling device used by base stations in CDMA communication systems. The scheduling device comprises a memory, a timer and a control unit.

The memory receives and stores data service request information for scheduling users and information about maximum scheduling resources for the system.

The control unit is connected to the timer output. The timer provides a time setting for the controller to perform downlink speed scheduling.

The control unit and the memory are interconnected. The controller is used to calculate scheduling user measurements, create a scheduling user queue, assign speeds according to the scheduling user queue and scheduling resources available to the system, remove a user who has obtained resources from the scheduling user queue, and send the assignment result to the selector and at least one channel unit.

Brief description of the drawings Figure 1 is a schematic diagram of a simplified CDMA communication system; Figure 2 is a schematic structural diagram of a base station incorporating the scheduling device of the present invention; Fig. 3 is a schematic structural diagram of the scheduling device of the present invention; Figure 4 is a flow chart of the scheduling method of the present invention; Figure 5 is a flow chart of the creation of a scheduling user queue according to the present invention; Figure 6 is a flow chart of a method for updating scheduling measurements according to the present invention.

Description of preferred embodiments Code Division Mutiple Access (CDMA) is a modulation technology for multiple access with the greatest competition in the new generation of mobile communications. To clarify the present invention, CDMA communication systems are initially introduced. As shown in Figure 1, a mobile station (MS) 107A or 107B communicates with a base station controller (BSC) 105A via a base transceiver station (BTS) 101A or 10IB. Sometimes MS can communicate with two base stations. For example, MS 107B communicates simultaneously with BTS 101A and 101B. The BSC 105A also communicates with the PSTN or ISDN via a mobile exchange exchange (MSC) 103. Meanwhile, an MSC 103 also connects to other BSC 105Bs.

As shown in Figure 2, it is a schematic structural diagram of a base station incorporating the scheduling device of the present invention. Data source 201 contains a quantity of packet data that needs to be sent to the remote MS 107. As differences in actual system implementations, data source 201 may be located in BSC 105 or MSC 103. A plurality of select units 205 and channel units 207 are located inside the base station. Selector unit 205 is used to control the communication between data source 201 and channel unit 207. Selector unit 205 and channel unit 207 are both controlled by scheduler 203. According to instructions from scheduler 203, selector unit 205 transmits the packet data stored in data source 201 to channel unit 207. Channel unit 207 performs a series of procedures for the data sent by selector unit 205.1 generally include these procedures: adding control bit, adding CRC bit, adding track bit, coding, inter-weaving, Wlash orthogonal modulation, and PN card code modulation, etc. Finally, transmitter 209 transmits the signals processed by channel unit to the remote MS.

For ease of illustration, the structure of the scheduling device of the present invention is introduced first. As shown in Figure 3, which represents the internal structure of the scheduler, the scheduler includes memory 301, timer 303 and controller 305. Memory 301 is used to store scheduling resource information available to the base station and data service request information. Scheduling resource information available to the base station includes resources of power, speeds, orthogonal codes, channel units, and so on. to be assigned by the base station to the MS requesting a data service. The data service request information includes identification of the mobile station requesting the data services, data traffic for the MS, request rates, MS scheduling measurements, the latest scheduling speeds, etc. Timer 303 provides timing for controller 305 to perform downlink speed scheduling. Timer 303 can be realized by using a system clock, an oscillator on the circuit board which locks on external signals, or a counter which is driven by a receiving system memory cell and which is synchronized with the external signals. At the time of scheduling, controller 305 performs speed scheduling for the MS requesting data service according to the information provided by memory 301, and sends the speed scheduling result to the relevant selector unit 204 and channel unit 207.

The present invention provides a method for downlink data scheduling in CDMA communication systems. The system includes at least one cell and at least one scheduling user.

The method of the present invention comprises the following steps: a. collect and obtain information about maximum scheduling resources available for a system and information about data service needs of scheduling users; b. calculate scheduling measures for scheduling users, where the scheduling measures include short-term scheduling measures, long-term scheduling measures and normalized long-term scheduling measures. c. create a scheduling user queue in accordance with the scheduling criteria; d. allocate speed and power according to the scheduling user queue and scheduling resources available to the system; e. remove the user who has obtained the resources from the scheduling user queue, and send the assignment result to a selector and at least one channel unit; and f. complete a scheduling cycle and wait for the scheduling of the next cycle according to the above steps.

The downlink rate scheduling method of the present invention further comprises the following steps after step e: checking if no scheduling resources are available for the system or the scheduling queue is empty; and if this is false, return to step e, or, if true, first update the scheduling measures for scheduling users and then perform step f.

The implementation of the above method can be continuously referred to Figure 4.1 Figure 4 denotes each step with a module, since the method according to the invention is realized by means of software forming part of control unit 305.1 module 401, control unit 305 acquires the information about the maximum scheduling resources available for the system. and the data service request information from memory 301, which forms a basis for the controller to schedule the speed. In module 403, the controller 305 creates the scheduling user queue according to the user scheduling measurements. The principle for creating the user queue is that the higher the priority of a scheduling user, the higher it is ranked in the scheduling user queue. In module 405, controller 305 assigns speeds to scheduling users according to the scheduling user queue sequence, which are limited by the currently available scheduling resources. In module 407, controller 305 removes the user who has obtained the resources from the scheduling user queue. Meanwhile, controller 305 notifies relevant selector unit 205 to send scheduling user data to channel unit 207. Channel unit 207 then processes the data according to the rate assigned by controller 305.1 module 409 repeats controller 305 procedures from module 405 to module 409 if controller 305 detects system stills and the scheduling user queue is not empty; otherwise, controller 305 executes module 411 directly to update the scheduling measurements for the scheduling users. In module 413, controller 305 waits for the next scheduling period and repeats the procedures from module 401 to module 411 according to the indication given by timer 303.

Please now study Figure 5.

In step c, the creation of a scheduling user queue is performed according to the following steps: cl. create an active scheduling user queue; c2. create an inactive scheduling user queue; c3. check if the long-term scheduling measure for an active scheduling user is greater than a fixed threshold constant TI; c4. check if the difference between the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user is greater than a fixed threshold constant T2; c5. inserting the inactive scheduler user in front of the active scheduler user and removing the inactive user from the inactive scheduler user queue; and c6. check whether all active scheduling users have been examined, and, if so, end the procedure, or, if not, repeatedly run steps c1 to c6 until all active scheduling users have been examined.

In the above step c3, the next step c4 is performed sequentially if the long-term scheduling measure of an active scheduling user is larger than the fixed threshold constant T1; otherwise step c6 is performed directly.

In the above step c4, the next step c5 is performed sequentially if the difference between the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user is greater than the fixed threshold constant T2; otherwise step c6 is performed directly.

For ease of description, we consider, as considered above, to divide the mobile stations involved in scheduling into two classes: an active scheduling user who has received the speed assigned by controller 305 in the most recent speed scheduling round; and an inactive scheduler user who has not received the speed assigned by controller 305.1 module 501 creates controller 305 the active scheduler user queue according to the normalized long-term scheduling measures for the active scheduler users. The smaller the normalized long-term scheduling measure for the active scheduling user, the higher it ranks in the active scheduling user queue. In module 503, controller 305 creates the inactive scheduling user queue according to the normalized long-term scheduling measures for the inactive scheduling users. The principle of this creation is the same as that in module 501. If in module 505 the controller 305 detects that the long-term scheduling measure of the active scheduling user satisfies equation (1), then module 507 is executed; otherwise, module 513 is executed. If in module 507, the controller 305 detects that the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user satisfy equation (2), then module 509 is executed; otherwise, module 511 is performed. T1 and T2 in equations (1) and (2) are all fixed threshold constants. By carefully selecting the threshold values T1 and T2, the speed scheduling for users can be performed evenly by the system. In module 509 for controller 305, the inactive scheduling user enters in front of the relevant active scheduling user, and removes the inactive scheduling user from the inactive scheduling user queue. In module 511, controller 305 detects whether all the inactive scheduling users have been browsed. If so, module 513 is executed; otherwise, the procedure is repeated from module 503 to module 513.

In module 515, controller 305 combines the active scheduling user queue and the inactive scheduling user queue (the active scheduling user queue precedes) to the scheduling user queue, and then the procedure of creating the scheduling user queue is completed. the long-term scheduling measure for the active scheduling user> T1 (1) (long-term scheduling measure for the active scheduling user) - (long-term scheduling measure for the inactive scheduling user)> T2 (2) It should be noted that the method for creating the scheduling user queue varies for different system implementations. For example, the controller can create the scheduling user queue solely based on the normalized long-term measure as the influence on the downlink utilization of signal overhead to create data service channels can be ignored. The smaller the normalized long-term scheduling measure for the scheduling user, the higher it ranks in the scheduling user queue. The invention encompasses all of these methods.

Please now study Figure 6. The procedure for updating the scheduling measure for scheduling users further includes the following steps: el. update the targeting speed for the scheduling user. Due to differences in application situations, the target rate may be the request rate obtained at the last packet call, or the maximum value of the most recent scheduling rates for the scheduling users, or the average of the most recent scheduling rates for the scheduling users; e2. update short-term scheduling metrics for scheduling users; e3. update the long-term scheduling metrics for scheduling users; and e4. update the standardized long-term scheduling metrics for scheduling users.

To facilitate illumination, the above steps are again described in the following manner in accordance with the above method: In module 603, controller 305 updates the short-term scheduling measure for the scheduling user. The definition of the short-term scheduling measure is given by equation (3): r denotes the instantaneous speed obtained by the scheduling user; R denotes the target rate for the scheduling user; ab denotes the weight factor relevant to the scheduling user. The weighting factors are related to the instantaneous speed obtained by the scheduling user and the resources consumed. The weighting factors of a cellular CDMA system where the downlink power is limited can, for example, be phased out of equation (4) if the instantaneous speed obtained by the scheduling user is, the nominal power consumed by base station 101 to support the speed is P (r) 0, and the actual power consumed of the base station to support the speed is P (r) jI equation (4) is a control factor that reflects the degree to which base station 101 prefers scheduling users who experience better wireless channel conditions. The larger the value edges, the more speed assignment opportunities are obtained by scheduling users with good wireless channel conditions, and the greater the capacity of the downlink resources. However, a too high & value will result in users with a poor wireless channel environment not being able to obtain speeds for a long time in the event that there are no system resources. Therefore, systems engineers should consider the balance between the following two aspects when choosing a value on factor k: (1) to increase the capacity of the downlink; and (2) to avoid the situation that the scheduling users with poor wireless channel environment for a long time can not obtain speed assignment or can only receive very low speed assignment.

Image available on "Original document" In module 605, the controller updates the long-term scheduling measure for the scheduling users. The long-term scheduling measure reflects the degree of resource allocation satisfaction for the scheduling users over a number of scheduling occasions. Assume that the short-term scheduling measure for a scheduling user witness scheduling rounds is S ^ n). The long-term scheduling measure for the scheduling user witness scheduling rounds, SL (n), is then: Image available on "Original document" where it is a constant.

In module 607, the controller 305 updates the normalized long-term scheduling measure for the scheduling user. The standardized scheduling measure reflects the average of the degree of resource allocation satisfaction for the scheduling users over the course of a plurality of scheduling rounds. Assume that the long-term scheduling measure for a scheduling user witness scheduling rounds is Si (n). Then the normalized long-term scheduling measure for the scheduling user witness scheduling rounds, SNL (n), is given by: Image available on "Original document" For a scheduling user receiving speed assignment for the first time, we assume that both the original long-term scheduling measure and the original normalized long-term scheduling measure for the user before the speed has been obtained are zero.

Soft switch is not discussed in connection with the procedure in module 607 above. As shown in Fig. 1, when mobile station 107A interrupts communication with base station 101 and begins communication with base station 101B, base station 10B should randomly assign a value of the original normalized long-term measure to mobile station 107A to ensure the smoothness of base station 10IB speed scheduling. . The initial value of the normalized long-term scheduling measure should be between the system's maximum and minimum values of the normalized long-term scheduling measure.

As for the step of updating the target speed for the scheduling users, the target speed reflects the speed desired by the users. The target speed can reflect this in different ways, depending on how the system is implemented. For example, it can be replaced by the request rate received by the scheduling user at the last packet call, or the maximum value or the average of the most recent scheduling speeds for the scheduling users. All of these forms of reflection are encompassed by the invention.

The embodiment described above illustrates and describes the invention. However, those skilled in the art can modify this embodiment without departing from the principle and scope of the invention. For example, the transmitted power in equation (4) can be replaced by received power, and the invention can also be used for speed scheduling of the uplink data service, which is not described in detail herein.

Industrial applicability With the above scheduling method and scheduling device, the invention can consider both the wireless environment and available system resources, effectively improve the utilization rate of the system resources, and reduce time delays in the transmission of scheduling user data. The present invention also contemplates fairness between scheduling users. In the meantime, scheduling evenness is also taken into account. With the scheduling smoothness, on the one hand, the times for creating and releasing data service channels can be reduced. In general, more signaling overhead is required to create and release service channels. The reduction in time required to create and free up data service channels means an increase in the degree of resource utilization. On the other hand, the degree of user satisfaction with the system can be ensured to some extent.

Claims (7)

A method for downlink speed scheduling, the method comprising the steps of: a. Collecting and obtaining information on maximum scheduling resources available to a system and information on data service needs from scheduling users; b. calculate scheduling measures for scheduling users, where the scheduling measures include short-term scheduling measures, long-term scheduling measures and normalized long-term scheduling measures; c. create a scheduling user queue in accordance with scheduling criteria; d. allocate speed and power according to the scheduling user queue and scheduling resources available to the system; e. remove the user who has obtained the resources from the scheduling user queue, and send the assignment result to a selector and at least one channel unit; and f. end a scheduling cycle and wait for scheduling of the next cycle according to the above steps. The method of claim 1, wherein the scheduling user queuing step c further comprises the following steps: cl. create an active scheduling user queue; c2. create an inactive scheduling user queue; c3. check if the long-term scheduling measure for an active scheduling user is greater than a fixed threshold constant TI; c4. check if the difference between the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user is greater than a fixed threshold constant T2; c5. inserting the inactive scheduler user in front of the active scheduler user and removing the inactive user from the inactive scheduler user queue; and c6. check whether all active scheduling users have been examined, and, if so, end the procedure, or, if not, repeatedly run steps c1 to c6 until all active scheduling users have been examined. The method of claim 2, wherein step c4 is performed in sequential order if in step c3 the long-term scheduling measure of an active scheduling user is greater than the fixed threshold constant T1; and otherwise step c6 is performed directly. The method of claim 2, wherein step c5 is performed in sequential order if in step c4 the difference between the long-term scheduling measure of the active scheduling user and the long-term scheduling measure of an inactive scheduling user is greater than the fixed threshold constant T2; and otherwise step c6 is performed directly. The method of claim 1, wherein the method further comprises the following step after step e: checking if no scheduling resources are available for the system or the scheduling queue is empty; and if this is false, return to step d, or, if true, first update the scheduling measures for scheduling users and then perform step f. The method of claim 5, wherein the procedure of updating the scheduling measure for scheduling users further comprises the following steps: el. updating scheduling users 'target rates, where the target rate may be a request rate for the most recent packet call, or the maximum value or average of the most recent scheduling users' scheduling rates; e2. update the short-term scheduling measure for scheduling users; e3. update the long-term scheduling measure for scheduling users; and e4. update the normalized long-term scheduling measure for scheduling users. A downlink rate scheduling device used by a base station in a CDMA communication system, the scheduling device comprising a memory, a timer and a controller; the memory receives and stores data service request information for scheduling users and information on maximum scheduling resources for the system; the controller is coupled to the output of the timer, which timer is used to provide timing for the controller to perform downlink speed scheduling; and the memory is linked to the controller which is used to calculate scheduling user measurements, create a scheduling user queue, assign speed according to the scheduling user queue and scheduling resources available to the system, remove a user receiving the resources from the scheduling user queue, and send the allocation to the allocation result unit .