KR102164275B1 - Single Metric Scheduling Method and Apparatus of Wireless Communication System - Google Patents

Abstract

The present invention relates to a method and apparatus for scheduling a single metric in a wireless communication system, in which data packets received from a plurality of wireless terminals are allocated to an opposite wireless terminal based on a time spent in a storage unit. Resources are allocated in consideration of the calculated time delay and the channel quality state of each wireless terminal, and the degree of the effect of the time delay is increased as time passes, and the calculated metric is used to increase the metric value. Resources are allocated to the terminal. Accordingly, not only can the quality of the wireless communication service be improved, but also the capacity of the wireless communication system can be increased and optimized.

Description

Single Metric Scheduling Method and Apparatus of Wireless Communication System

The present invention relates to a method and apparatus for scheduling a single metric in a wireless communication system. Specifically, resources are allocated in consideration of a time delay and a channel state when communicating with a wireless terminal and a base station. The present invention relates to a method and apparatus for scheduling a single metric in a wireless communication system that optimizes the capacity of a wireless communication system and improves the quality of a communication service by scheduling using a single metric whose influence of delay changes.

In general, a mobile communication base station has a scheduler that allocates resources to a user's wireless terminal. The scheduler is responsible for allocating resources of the wireless communication system to each wireless terminal by reflecting the request specifications and channel conditions of each wireless terminal. Conventionally, in order to provide data services to a plurality of wireless terminals, a scheduler allocates resources by using various resource scheduling methods.

Among the scheduling methods, the maximum communication quality (Max C/I) method is widely used to optimize the capacity of a wireless communication system, and is the largest C/I based on the communication quality of each wireless terminal channel. The resource is preferentially allocated to a wireless terminal with an I value. Here, C is the power of the received signal component, and I is the power of the received interference and noise components. The metric used at this time can be expressed by the following equation.

Here, C _k (t) means the C/I value of the k-th user, and the metric becomes a function of time t and changes with time.

Resource allocation based on the maximum communication quality has a disadvantage in that resource allocation can be concentrated only to wireless terminals in a specific good environment because resources are allocated to wireless terminals with good channel conditions. In other words, there is a problem with fairness.

A proposed method to solve this equity problem is a proportional fair method, which is disclosed in Korean Patent Application Publication No. 2007-0068930. In the proportional fairness scheme, resources are allocated based on the channel state relative to the average of each wireless terminal. That is, resources are allocated when the channel status of the wireless terminal is better than the average channel status. The resource allocation metric of the proportional fairness method is as follows.

Here, R _k (t) is a data rate that can be transmitted to the channel of the k-th wireless terminal, and T _k (t) is the average data throughput of the k-th wireless terminal. Generalizing this metric equation gives R _k ^α (t) / T _k (t) ^β , where α,β are parameters used to represent fairness, and α,β are all 0 to 1 It has a value (0≤α≤1, 0≤β≤1), preferably α+β=1.

As described above, both the maximum communication quality method and the proportional fair method allocate resources in consideration of only the channel state, and do not reflect the effect on the time delay.

As an algorithm that reflects the time delay or the size of the buffer in the queue, there is a M-LWDF (Modified largest weighted delay first) method that considers the channel state and time delay, and Korean Patent Publication Nos. 2005-24938 and 2007-0000371 It is disclosed in In this algorithm, resource allocation is performed by considering the time delay and the channel state as shown in the following equation.

Here, d _k is a constant, and W _k (t) represents the time delay or queue length of the head-of-line packet. W _k (t) is a weight, and the M-LWDF metric is obtained by multiplying the proportional fair metric by a weight of W _k (t).

1 is a graph of the weight function W _k (t) in the conventional M-LWDF algorithm, and it can be seen that the weight function increases linearly with the delay component. That is, by assigning weights to long-awaited wireless terminals, resources are preferentially allocated to long-awaited wireless terminals.

This M-LWDF method uses a metric that considers both time delay and channel state. However, as shown in FIG. 1, as the weight function increases linearly with a certain slope, there is a disadvantage in that the weight for the time delay is excessively applied and the effect on the time delay becomes too large. Accordingly, there is an inefficiency in optimizing the capacity of the wireless communication system. In addition, the M-LWDF method does not have the flexibility to change the parameter of the metric into a form similar to the maximum communication quality method or the proportional fair method.

As described above, since the conventional resource allocation schemes perform resource scheduling using different metrics, different metrics are used if their optimization targets are different, and scheduling is performed in different frameworks according to the use of different metrics. Therefore, the resource management program becomes complicated, and it becomes difficult to find an efficient method when resource management and scheduling must be performed by negotiating two or more purposes.

In the present invention, not only resources are allocated in consideration of both time delay and channel state, but also a desired service by changing a parameter of a metric by performing scheduling using a single metric that can integrate various existing metrics into one. A single metric scheduling method and apparatus for a wireless communication system capable of achieving quality (QoS) is proposed.

The object is a storage unit for storing data packets received from a plurality of wireless terminals; And, when allocating resources for transmitting the data packet stored in the storage unit to the other wireless terminal, a time delay calculated based on the time the data packet stays in the storage unit, and each radio provided from the plurality of wireless terminals. It can be achieved by a single metric scheduling apparatus of a wireless communication system, characterized in that it allocates resources in consideration of the channel quality state of the terminal, and includes a scheduler that increases the degree of influence of the time delay as time passes. .

The object is to store data packets received from a plurality of wireless terminals; Calculating a time delay in which the data packet stays in a storage unit of a base station, and receiving channel quality status of each wireless terminal from the plurality of wireless terminals; Scheduling step of allocating resources to transmit the data packet stored in the storage unit to the opposite wireless terminal in consideration of the time delay and the channel quality state, but increasing the effect of the time delay as the time delay increases. It can also be achieved by a single metric scheduling method of a wireless communication system comprising;

According to the method and apparatus for scheduling a single metric in a wireless communication system of the present invention, the delay time is divided into a plurality of sections, and the degree of influence of the delay time on resource allocation in each section is different, and the channel state is considered together. By configuring the metric, it is possible to optimize the capacity of the wireless communication system and improve the quality of service.

1 is a graph of a weight function W _k (t) of a conventional proportional fairness algorithm;
2 is a configuration diagram of a wireless communication base station according to an embodiment of the present invention;
3 is a graph of a weight function of the scheduling algorithm according to the first embodiment of the present invention;
4 is a graph of a weight function of a scheduling algorithm according to a second embodiment of the present invention;
5 is a flowchart illustrating a process of allocating resources by a scheduling algorithm according to another embodiment of the present invention.
6 is a diagram showing a configuration of a user terminal according to another embodiment.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to constituent elements of each drawing, it should be noted that the same constituent elements have the same reference numerals as possible, even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

2 is a configuration diagram of a wireless communication base station according to an embodiment of the present invention.

The wireless communication system according to the present invention includes a base station 100 that schedules data packets received from a plurality of wireless terminals and transmits them to a counterpart wireless terminal.

The base station 100 includes a control unit 120, a transmission unit 150, and a reception unit 110.

The control unit 120 controls the overall operation of the base station according to the scheduling method for allocating resources of the communication system necessary for carrying out the present invention.

The transmitting unit 150 and the receiving unit 110 are used to transmit and receive signals, messages, and data necessary for carrying out the above-described present invention with the terminal.

The wireless communication base station 100 according to an embodiment of the present invention includes a control unit 120 including a scheduler 130 for scheduling a single metric that allocates resources in consideration of time delay and channel conditions, and a plurality of A receiver 110 that receives uplink control information, data and messages from a wireless terminal, a transmitter 150 that processes scheduled data packets and transmits them to the other wireless terminal, and a data packet received through the receiver 110 It may include a storage unit 140 for storing them.

When resources are allocated by the scheduler 130, the controller 120 provides data packets received from the wireless terminal to the transmission unit 150 according to the resource allocation order, and can control the overall operation of the base station 100. .

The scheduler 130 may allocate resources of the wireless communication system by using a single metric scheduling algorithm that considers time delay and channel conditions in order to transmit information received from a plurality of wireless terminals to the opposite wireless terminal. The scheduling algorithm used by the scheduler 130 will be described later.

In the present invention, it is described that the control unit 120 includes the scheduler 130, but of course, the scheduler 130 may be provided separately from the control unit 120. Regardless of whether the scheduler 130 belongs to the control unit 120 or not, the scheduler 130 and the storage unit 140 may operate as a scheduling device.

The storage unit 140 generally refers to a storage means used in the base station 100, and in the present invention, a case of using a queue as the storage unit 140 will be described as an example.

A detailed description of a single metric scheduling algorithm used to allocate resources in the scheduler 130 is as follows.

The single metric scheduling algorithm used by the scheduler 130 may use a single metric (M) for scheduling resource allocation in consideration of a time delay and a channel state at the same time. Equation 1 below is a formula for calculating a single metric according to the present invention.

[Equation 1]

Here, d _k is a constant, R _k (t) is the data rate that can be transmitted through the channel of the k-th wireless terminal, and T _k (t) is the average data throughput of the k-th wireless terminal. The weight function f is given as a function with two variables, W _k (t) and C _i (t), where W _k (t) represents the packet delay or queue length, and C _i (t) represents the channel Is the C/I or SNR representing the signal quality of. Here, α,β are parameters used to indicate fairness, and α,β both have values from 0 to 1 (0≤α≤1, 0≤β≤1), preferably α+ may be β=1.

The single metric of the present invention is a weighted ratio of f (W _k (t), C _i (t)) to a proportional fair scheme that allocates resources based on the channel state relative to the average of each radio terminal. I can. Here, the weight function f(W _k (t), C _i (t)) consists of one variable called time delay or queue length, and another variable called channel state, and when the delay time of the data packet increases It can be set to increase the effect of the time delay.

In this case, the weight function f may change the shape according to the probability of data outage required by the wireless communication system. In particular, the value of the f function for the maximum allowable time delay W can be set by the data disconnection probability. Here, the data disconnection is a phenomenon in which data is disconnected due to a longer delay time of the packet data transmitted to the wireless terminal. When the time that the data packet stays in the queue is greater than a certain interval between data packets, the data disconnection occurs. That is, in the present scheduling algorithm, the weight function f is set to change according to the probability of data disconnection, so that resources are adaptively allocated according to the time delay of the data.

3 is a graph of a weight function of a scheduling algorithm according to the first embodiment of the present invention.

In the first embodiment, in order to simplify the implementation and to be able to grasp the resource allocation method of the scheduling algorithm according to the time delay, the weight function f is a function of the variable W _k (t) representing the time delay or the length of the queue. Shows the case.

In the first embodiment, as shown in FIG. 3, the function f may be set to be divided into two sections according to a time delay. The time delay is divided into a section from 0 to W ₁ and a section from W ₁ to W ₂ . Here, it can be seen that the slope between (W ₁ , W ₂ ) is greater than the slope between (0, W ₁ ).

In FIG. 3, b, which is the value of f(W ₂ ), is determined under the influence of the data disconnection probability of the wireless communication system. In the first embodiment, if a, which is the value of f(W ₁ ) in the weight f function, is fixed and W ₁ is increased, the metric becomes similar to the proportional fair method in which resources are allocated based on the channel state relative to the average of each wireless terminal. Able to know. In addition, if the slope between (W ₁ , W ₂ ) and the slope between (0, W ₁ ) are the same, it becomes the same as the metric of M-LWDF.

According to this single metric scheduling algorithm, it can be seen that the effect of the time delay does not increase linearly over the entire period as in the proportional fair method, but the degree of the effect of the time delay varies according to the time period. In the first section, the effect of the time delay increases as time goes by, but the degree of increase is not steep. On the other hand, in the second section, it can be seen that as time passes, the effect of the time delay changes relatively rapidly compared to the first section. That is, the delayed time is divided into a plurality of sections so that the effect of the time delay is small during an initial predetermined time, but the effect of the time delay is largely reflected in the section after the predetermined time.

4 is a graph of a weight function of a scheduling algorithm according to a second embodiment of the present invention.

In the second embodiment, the scheduler 130 sets a value of a function f (W _k (t)), which is a weight, so that the time interval is divided into three intervals according to the time delay. The time delay section is divided into (0, W ₁ ), (W ₁ , W ₂ ), (W ₂ , W ₃ ), and as the time delay increases, the slope of each section gradually increases. That is, the longer the delay time, the greater the effect of the time delay when allocating resources.

In the first section, the time zone study period (0, W ₁ ), the weight is maintained as a constant, and in this embodiment, 1 is set as a constant. Accordingly, the slope of the first section becomes 0, and becomes a section operating in a proportional fairness method or a Max C/I method in which resources are preferentially allocated to a radio terminal having a good channel state. In this first section, the capacity of the wireless communication system can be maximized, and accordingly, it can be referred to as a system capacity maximization section.

In the second section, the time zone study period (W ₁ , W ₂ ), an example in which the weight f is maintained in a linear shape with a larger slope than the first section is shown. In addition, in the third section, the weight f has a larger slope than the second section.

The value b of the weight f(W ₃ ) in the third period, the time delay period (W ₂ , W ₃ ), is determined using the data disconnection probability of the wireless communication system. In the weight f function of FIG. 3, if a, which is the value of f(W ₁ ), is fixed and W ₁ is increased, it can be seen that the metric becomes similar to the proportional fairness method in which resources are allocated based on the channel state relative to the average of each wireless terminal. have.

The weight function of the resource allocation algorithm according to the second embodiment is set to divide a time section into three sections, and as in the first embodiment, the effect of the time delay of each section is designed to increase as time elapses. In other words, the longer a radio terminal belonging to the third delay section, the higher the probability of resource allocation, and this section may be referred to as a delay limit section because further time delay is limited in this section.

Meanwhile, in the above-described embodiment, a metric is calculated by adding a weight to the data rate R _k (t) that can be transmitted in the channel. However, by multiplying a weight _{f (W k (t),} C i (t)) in the C _k (t) which is the value of C / I or SNR represents the signal quality of the channel can create a new metric. Equations 2 and 3 below are examples of another type of metric proposed by the present invention.

[Equation 2]

[Equation 3]

Here, W _k (t), which is a variable of the weight function f, represents the time delay of the packet or the length of the queue, and C _i (t) is the C/I or SNR representing the signal quality of the channel. And K and M are constants.

As shown in Equation 2 and Equation 3, as shown in Figs. 3 and 4, the time delay section is divided into a plurality of sections by adjusting the weight f(W _k (t)), according to the time delay. It is possible to control the scheduling of resources of the wireless communication system.

Hereinafter, a process of allocating resources by the scheduling algorithm of the present invention will be described with reference to FIG. 5.

5 is a flowchart illustrating a process of allocating resources by a scheduling algorithm according to another embodiment of the present invention.

5, when the receiving unit 110 of the base station 100 receives data packets from a plurality of wireless terminals (S500), the control unit 120 stores the data packets in a queue, which is the storage unit 140 (S510). ), the scheduler 130 is operated.

Then, the control unit 120 provides information on the channel state provided from each wireless terminal to the scheduler 130, while information on the delay time or the length of the queue at which data packets from each wireless terminal stay in the queue. Is provided to the scheduler 130 in real time (S520).

Then, the scheduler 130 divides the delayed time of the data packet into a plurality of sections (S530), and determines the weight function f of each section so that the effect of the time delay increases as the time delay increases (S540).

For example, the weight of the first section among a plurality of sections is set to be constant or close to a constant so that it is relatively less affected by time delay than other sections, and the last section is relatively affected by time delay compared to other sections. Set the weight function to receive more. In addition, the scheduler 130 determines b, which is a value of the weight f(W ₃ ) of the last section, using the data disconnection probability of the wireless communication system.

The scheduler 130 calculates a metric value by substituting the determined weight function into a metric (S550), and preferentially allocates a resource to a wireless terminal having a large calculated value (S560). In this case, as described above, the scheduler 130 may calculate a metric value by selecting one of the metrics disclosed in Equations 1 to 3.

6 is a diagram showing a configuration of a user terminal according to another embodiment.

Referring to FIG. 6, a user terminal 600 according to another embodiment includes a reception unit 610, a control unit 620, and a transmission unit 630.

The receiving unit 610 receives downlink control information, data, and messages from the base station through a corresponding channel.

In addition, the control unit 620 controls the overall operation of the terminal according to the scheduling method for allocating resources of the communication system required for carrying out the present invention.

The transmitter 630 transmits downlink control information, data, and a message to the base station through a corresponding channel.

A method and apparatus for scheduling a single metric in a wireless communication system of the present invention proposes a scheduling method using a single metric for allocating resources. In the scheduling method of the present invention, a metric considering both a time delay and a channel state is used, and the delayed time is divided into a plurality of sections, and the effect of the time delay is set to increase as the elapsed time of each section increases. Accordingly, the longer the waited wireless terminal, the larger the metric value, and the resource is allocated to the wireless terminal having a larger calculated metric value, so that the long-waited wireless terminal can be allocated resources. Accordingly, not only can the quality of the wireless communication service be improved, but also the capacity of the wireless communication system can be increased and optimized.

The standard contents or standard documents mentioned in the above-described embodiments are omitted to simplify the description of the specification and constitute a part of the specification. Accordingly, it should be construed as falling within the scope of the present invention to add the contents of the standard contents and some of the standard documents to the present specification or to describe in the claims.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

100: base station 110: receiver
120: control unit 130: scheduler
140: storage unit 150: transmission unit

Claims (13)

A storage unit for storing data packets received from a plurality of wireless terminals; And,
When allocating a resource for transmitting the data packet stored in the storage unit to the other wireless terminal, the time delay calculated based on the time the data packet stays in the storage unit, and each wireless terminal provided from the plurality of wireless terminals It allocates resources in consideration of the channel quality state, and includes a scheduler that increases the degree of influence according to the time delay as time elapses,
Wherein the scheduler divides the delay time of the data packet into a plurality of sections, and applies a weighting function having the time delay and the channel quality state as variables for each of the plurality of sections differently from each other. A single metric scheduling device in the system. The method of claim 1,
The scheduler, a single metric scheduling apparatus for a wireless communication system, characterized in that for scheduling resources by using the metric of Equation 1 below.
[Equation 1]

Here, d _k is a constant, R _k (t) is the data rate that can be transmitted through the channel of the k-th wireless terminal, T _k (t) is the average data throughput of the k-th wireless terminal, and W _k (t) is Packet time delay or queue length, C _i (t), is C/I or SNR indicating the signal quality of the channel. The method of claim 1,
The scheduler, a single metric scheduling apparatus for a wireless communication system, characterized in that for scheduling resources using the metric of Equation 2 below.
[Equation 2]

Here, W _k (t) is the packet time delay or the length of the queue, and C _i (t) and C _k (t) are C/I or SNR indicating the signal quality of the channel. The method of claim 1,
The scheduler, a single metric scheduling apparatus for a wireless communication system, characterized in that for scheduling resources by using the metric of Equation 3 below.
[Equation 3]

Here, W _k (t) is the packet time delay or queue length, C _i (t) and C _k (t) are C/I or SNR indicating the signal quality of the channel, and K and M are constants. The method according to any one of claims 2 to 4,
And the scheduler sets a function f, which is a weight of the metric, so that the effect of the time delay on resource allocation in each of the plurality of intervals is different. The method of claim 5,
Wherein the scheduler sets a weight of a first section of the plurality of sections to be constant or close to a constant to be relatively less affected by a time delay than other sections. The method of claim 5,
The scheduler, the single metric scheduling apparatus of a wireless communication system, characterized in that to determine the start point of the last section of the plurality of sections based on a data disconnection probability required by the wireless communication system. The method of claim 5,
Wherein the scheduler sets a weight function such that a last section of the plurality of sections is more affected by a time delay than other sections. Storing data packets received from a plurality of wireless terminals;
Calculating a time delay in which the data packet stays in a storage unit of a base station, and receiving channel quality status of each wireless terminal from the plurality of wireless terminals;
Scheduling step of allocating resources to transmit the data packet stored in the storage unit to the opposite wireless terminal in consideration of the time delay and the channel quality state, but increasing the effect of the time delay as the time delay increases. Including ;,
The scheduling step is a radio, characterized in that the data packet delay time is divided into a plurality of sections, and a weighting function having the time delay and the channel quality state as variables is applied differently to each of the plurality of sections. Single metric scheduling method of communication system. The method of claim 9,
The scheduling step is a single metric scheduling method of a wireless communication system, characterized in that the resource is scheduled using the metric of Equation 1 below.
[Equation 1]

Where d _k is a constant, R _k (t) is the data rate that can be transmitted through the channel of the k-th wireless terminal, T _k (t) is the average data throughput of the k-th wireless terminal, and W _k (t) is a packet The time delay or the length of the queue, C _i (t) is the C/I or SNR representing the signal quality of the channel. The method of claim 9,
The scheduling step is a single metric scheduling method of a wireless communication system, characterized in that the resource is scheduled using the metric of Equation 2 below.
[Equation 2]

Here, W _k (t) is the packet time delay or the length of the queue, and C _i (t) and C _k (t) are C/I or SNR indicating the signal quality of the channel. The method of claim 9,
The scheduling step is a single metric scheduling method of a wireless communication system, characterized in that the resource is scheduled using the metric of Equation 3 below.
[Equation 3]

Here, W _k (t) is the packet time delay or queue length, C _i (t) and C _k (t) are C/I or SNR indicating the signal quality of the channel, and K and M are constants. The method according to any one of claims 10 to 12,
The scheduling step,
A single metric scheduling method for a wireless communication system, characterized in that, in each of the plurality of sections, a function f, which is a weight of the metric, is set so that the effect of the time delay on resource allocation is different.

Images