KR20210062439A - TCP-compatible optimal CSMA-based resource allocation in wireless network - Google Patents

Abstract

The present invention relates to a CSMA-based optimal resource allocation method considering interoperability with TCP in a wireless communication network. The purpose of the present invention is to make adaptive driving to a radio interference situation showing variable characteristics according to time in a situation where a plurality of terminals are to communicate by occupying radio resources with each other without an access point (AP) in a wireless ad hoc network situation, so that each wireless connection is equally assigned with radio resources. For the fairness of this resource allocation, provided is a technology in which the length of a transmission queue (media access queue, MAQ) for determining the occupancy status of a radio resource of a terminal and an MAQ delay for compatibility with TCP are measured to be applied to a contention window (CW) which is a channel access parameter. The CW parameter can be set as an 802.11 DCF parameter to adjust transmission aggressiveness when sending packets to a physical layer. In addition, provided is a priority scheduling method for guaranteeing quality-of-service (QoS) of a terminal using wireless communication.

Description

CSMA-based optimal resource allocation method considering interoperability with TCP in wireless communication network {TCP-compatible optimal CSMA-based resource allocation in wireless network}

The present invention relates to a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network.

The present invention assumes a situation in which a plurality of terminals attempt to communicate by occupying radio resources with each other without an access point (AP) in a wireless ad-hoc network situation. The radio resource allocation control (Medium Access Control, MAC) algorithm in the unlicensed band is defined in the 802.11 standard. DCF (Distributed Coordinated Function), a resource allocation technology that is distributedly driven in the 802.11 standard, implements the distribution of radio resources in a distributed manner by independently adjusting the CW (Contention Window), a channel access parameter, without a centralized processor. have. The CW parameter specifies the waiting time before attempting to occupy a radio channel, a low CW parameter means high aggressiveness for occupying a radio channel, and a high CW parameter means low aggressiveness for occupying a radio channel.

According to the current 802.11 DCF standard, the minimum unit of the CW parameter is 9 us (microseconds), and when the first transmission is attempted, the CW is randomly selected from 0 to 15 units, and the terminal to occupy the radio resource is randomly selected. If a collision occurs with a high probability when CW is selected from 0 to 15 units due to a large number of terminals, the CW parameter selection is exponentially backoff and randomly selected in the order of 0 to 31, 0 to 63, and so on. It is done. The currently implemented DCF technology achieves high utilization of radio resources by adaptively operating in various radio interference situations in the manner described above.

However, the conventional DCF technology does not guarantee that the fairness of radio resource distribution for each radio terminal will be achieved. The issue of fairness in radio resource distribution becomes more serious especially in a situation where the terminal is miniaturized and requires low-power wireless communication. [Fig. 1] shows a simple interference situation in which six terminals attempt to perform communication. In [Fig. 1], there are three wireless transmissions, the transmission of the middle terminal receives more interference than the transmission on both sides. A situation in which any of the UEs in the same space receives more interference is referred to as an asymmetric interference situation. A terminal that receives a lot of interference does not have an opportunity to transmit, and a terminal that receives less interference determines that it does not need to give up relatively, and continues to occupy a radio channel. If this situation persists, a terminal that receives a lot of interference can hardly take a radio channel, and there is a problem in that extreme resource allocation asymmetry occurs.

An object of the present invention is to provide a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network.

In addition, an object of the present invention is to directly measure the occupied state of a radio resource of a terminal and reflect it in a channel access parameter CW (Contention Window).

In addition, an object of the present invention is to adjust transmission aggressiveness by using a transmission queue delay (MAQ delay) for compatibility with TCP.

In addition, it is an object of the present invention to propose a method of using a priority scheduling method to ensure quality-of-service (QoS) of a connection.

In addition, an object of the present invention is to design and propose a technology driven as a protocol through a design modification of the MAC layer of the 802.11 DCF algorithm.

In order to solve the above problems, the present invention provides a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network. In the optimal resource allocation method, the step of performing priority scheduling to guarantee a quality-of-service (QoS) connection; In the optimal resource allocation method, a media access queue (MAQ) length for determining an occupied state of a radio resource of a terminal and a MAQ delay for compatibility with TCP are determined. Measuring; Determining CWmin, which is a channel access parameter, using the measured MAQ length and MAQ delay; And adjusting the transmission aggressiveness by setting the determined CWmin value as an 802.11 DCF parameter.

According to an embodiment, in the step of performing the priority scheduling, the Media Access Queue (MAQ) is divided into Low Priority Queue (LPQ) and High Priority Queue (HPQ), and the priority of the transport packet According to this, the quality-of-service (QoS) of the connection can be guaranteed by buffering each of the LPQ and HPQ.

According to an embodiment, in the step of measuring the MAQ delay, a method of measuring the time spent in the transport packet in the Low Priority Queue (LPQ) and the Hight Priority Queue (HPQ) is used.

According to an embodiment, in the step of measuring the MAQ delay, buffering from the Control Queue (CQ) to the Media Accdess Queue (MAQ) is adjusted according to the measured MAQ delay. When mixed, transmission fairness can be provided between multiple connections.

According to an embodiment, in the step of measuring the MAQ delay, intra-scheduling of scheduling the IFQ in the order of the largest MAQ delay is performed according to the measured MAQ delay.

According to an embodiment, in the step of determining CWmin as the channel access parameter, a method of assigning a weight to CWmin according to which queue of the LPQ or HPQ the MAQ packet is stored is provided.

The present invention is a terminal that performs a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network, comprising: a transceiver configured to transmit or receive a signal including a packet;

Priority Scheduling is performed to ensure the quality of service (Quality-of-Service, QoS) of the connection, and the length of the media access queue (MAQ) to determine the occupancy status of the radio resource of the terminal ( MAQ length) and the transmission delay of MAQ for compatibility with TCP (MAQ delay),

A processor that determines CWmin as a channel access parameter using the measured MAQ length and MAQ delay, sets the determined CWmin value as an 802.11 DCF parameter, adjusts transmission aggressiveness accordingly, and transmits a packet to the physical layer Provides.

According to at least one embodiment of the present invention, by applying a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network, efficiency and fairness of radio resource distribution can be achieved in a time-variable and asymmetric radio interference situation. You will be able to.

According to at least one embodiment of the present invention, a radio resource occupancy state of a terminal is directly measured and reflected in a channel access parameter, a contention window (CW), so that all terminals can be fairly allocated radio resources.

According to at least one embodiment of the present invention, for compatibility with TCP, transmission aggressiveness is adjusted using a transmission queue delay (MAQ delay) to control congestion of TCP when the TCP is operated at the transmission layer. As the function is used, it is possible to solve the problem of not being allocated radio resources.

According to at least one embodiment of the present invention, by providing a priority scheduling method, quality-of-service (QoS) of a connection requiring high real-time such as voice/video communication can be improved. I can.

According to at least one embodiment of the present invention, by providing an optimal resource allocation method through a design modification of the MAC layer of the 802.11 DCF algorithm, interoperability with the standard 802.11 DCF may be provided.

Accordingly, when the present invention is applied, radio resources can be equally allocated to all terminals irrespective of the interference situation in a time-variable and asymmetric radio interference situation, thereby increasing the effectiveness of a wireless communication network.

1 shows an asymmetric radio interference situation according to the present invention.
2 shows a structural diagram of a modified design of the MAC layer according to the present invention.
3 shows a structural diagram of priority scheduling for guaranteeing QoS according to the present invention.
4 is a flowchart illustrating a process of a terminal according to the present invention in the system of FIG. 2.
5 is a block diagram of a mobile communication terminal including a transceiver and a processor according to the present invention.

The features and effects of the present invention described above will become more apparent through the following detailed description in connection with the accompanying drawings, and accordingly, those of ordinary skill in the technical field to which the present invention pertains can easily implement the technical idea of the present invention. I will be able to.

In the present invention, various modifications may be made and various embodiments may be provided, and specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

In describing each drawing, similar reference numerals are used for similar elements.

Terms such as first and second may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another component.

For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element. The term and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

Unless otherwise defined, all terms used herein including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs.

Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. Shouldn't.

Suffix modules, blocks, and parts for components used in the following description are given or mixed in consideration of only the ease of writing the specification, and do not have meanings or roles that are distinguished from each other by themselves.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement them. In describing the embodiments of the present invention below, when it is determined that a detailed description of a related known function or a known configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

Hereinafter, a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network according to the present invention will be described.

The present invention assumes a situation in which a plurality of terminals attempt to communicate by occupying radio resources with each other without an access point (AP) in a wireless ad-hoc network situation. The technology proposed in the present invention aims to be adaptively driven in a radio interference situation exhibiting variable characteristics over time, so that radio resources are equally allocated to each radio connection.

Currently, the radio resource allocation control (Medium Access Control, MAC) algorithm in the unlicensed band is defined in the 802.11 standard. DCF (Distributed Coordinated Function), a resource allocation technology that is distributedly driven in the 802.11 standard, implements the distribution of radio resources in a distributed manner by independently adjusting the CW (Contention Window), a channel access parameter, without a centralized processor. have. The CW parameter specifies the waiting time until attempting to occupy a radio channel, a low CW parameter means high aggressiveness for occupying a radio channel, and a high CW parameter means low aggressiveness for occupying a radio channel.

According to the current 802.11 DCF standard, the minimum unit of the CW parameter is 9 us (microseconds), and when the first transmission is attempted, the CW is randomly selected from 0 to 15 units, and the terminal to occupy the radio resource is randomly selected. If a collision occurs with a high probability when CW is selected from 0 to 15 units due to a large number of terminals, the CW parameter selection is exponentially backoff and randomly selected in the order of 0 to 31, 0 to 63, and so on. It is done. The currently implemented DCF technology achieves high utilization of radio resources by adaptively operating in various radio interference situations in the manner described above.

However, the conventional DCF technology does not guarantee that the fairness of radio resource distribution for each radio terminal will be achieved. The issue of fairness in radio resource distribution becomes more serious especially in a situation where the terminal is miniaturized and requires low-power wireless communication. [Fig. 1] shows a simple interference situation in which six terminals attempt to perform communication. In [Fig. 1], there are three wireless transmissions, the transmission of the middle terminal receives more interference than the transmission on both sides.

A situation in which any of the UEs in the same space receives more interference is referred to as an asymmetric interference situation. A terminal that receives a lot of interference does not have an opportunity to transmit, and a terminal that receives less interference determines that it does not need to give up relatively, and continues to occupy a radio channel. If this situation persists, a terminal that receives a lot of interference can hardly take a radio channel, resulting in extreme resource allocation asymmetry.

In order to solve this problem of fairness of resource allocation, the technology proposed in the present invention proposes a technology that directly measures the occupied state of a radio resource of a corresponding terminal and reflects it in a CW parameter. In order to measure the occupancy state, the measure proposed in the present invention is the transmission queue length. When the transmission queue length is short, radio resources are well occupied for the transmission request amount, and when the queue length is long, the transmission request amount is regarded as a situation in which the radio resource occupancy amount is not handled. If radio resources are allocated in this manner, radio resources can be optimally allocated to all terminals.

The present invention designs and proposes a technology driven as a protocol through modification of an actual 802.11 DCF algorithm based on this theoretical basis. [Fig. 2] is a structural diagram of the present invention. In data communication, the present invention can be implemented by changing only the design of the MAC layer without changing the transport layer and the physical layer. First, the classification 210 classifies the packets from the transport layer by destination and puts them in different control queues 220. The link rate regulator 230 performs scheduling for equally dropping the packets down to each control queue 220 to the medium access queue 240. Thereafter, the Link Price Calculator 250 measures a transmission queue length (MAQ length) and a transmission waiting delay of MAQ for compatibility with TCP in order to determine the state of occupancy of the radio resource of the terminal. There is a problem in that the transmission aggressiveness of a terminal that cannot be allocated radio resources cannot be effectively increased as the congestion control function of TCP is used when TCP is running at the transmission layer. In this case, the MAQ delay is reduced. This starvation problem can be solved by adjusting the transmission aggressiveness by using.

The Link Price Calculator 250 determines the CWmin parameter using the measured MAQ length and MAQ delay, and this value is set as an 802.11 DCF parameter. ) Can be adjusted.

In this way, MAQ lengh and MAQ delay are reflected as CWmin parameters to participate in radio resource access.

In addition, in the present invention, in order to guarantee the quality-of-service (QoS) of a connection using wireless communication, the transmission priority of communication packets is classified using a priority scheduling method. Packets with high priority have the minimum delay at the corresponding layer, so they are suitable for traffic requiring high real-time properties such as voice/video communication, and packets with low priority do not require relatively real-time performance. It is suitable for unused Internet traffic or report packets of sensor networks.

[Fig. 3] shows in detail the priority scheduling scheme proposed in the present invention.

First, the Media Access Queue (MAQ) 240 is a Low Priority Queue (LPQ) 241 for buffering packets with a low priority and a High Priority Queue (HPQ) 242 for buffering packets with a high priority. It is managed by dividing it into. The link rate regulator 230 divides the packet transmitted from the control queue 220 into the LPQ 241 and the HPQ 242 according to transmission priority and buffers the packet. Thereafter, when the Link Price Calculator 240 measures the MAQ length and the MAQ delay to determine the CWmin value, a weight is given to the CWmin value according to the LPQ 241 or the HPQ 242. That is, the packet is the HPQ 242. If it is, the CWmin value is lowered to have high aggressiveness for occupying a wireless channel, thereby ensuring a quality-of-service (QoS) of a connection using wireless communication.

4 is a flowchart illustrating a process of a terminal in a CSMA-based optimal resource allocation method considering interoperability with TCP in a wireless communication network. Referring to [Fig. 4], the step of performing priority scheduling (S110), measuring the transmission queue length and the transmission waiting delay of the MAQ (S120), determining the CWmin (S130), and adjusting the transmission aggressiveness (S140) ).

In the prioritization scheduling step (S110), the optimal resource allocation method may perform priority scheduling to guarantee quality-of-service (QoS) of the connection.

In addition, the optimal resource allocation method includes a media access queue (MAQ) length for determining the occupied state of a radio resource of a terminal and a MAQ delay for compatibility with TCP. It further includes a step of measuring (S120).

In addition, the optimal resource allocation method is the step of determining CWmin as a channel access parameter using the measured MAQ length and MAQ delay (S130), and adjusting the transmission aggressiveness by setting the determined CWmin value as an 802.11 DCF parameter. The step 140 further comprises.

5 shows a block diagram of a mobile communication terminal 300 including a transceiver 310 and a processor 320 according to the present invention. Referring to FIG. 5, the mobile communication terminal 300 includes a transceiver 310 and a processor 320.

The transceiver 310 is configured to transmit or receive a signal including a packet. Meanwhile, the processor 320 is configured to perform priority scheduling in order to guarantee quality-of-service (QoS) of the connection. In addition, the processor 320 measures a transmission queue (MAQ length) for determining the state of occupancy of radio resources of the terminal and a MAQ delay for compatibility with TCP. can do. In addition, the processor 320 may determine the channel access parameter CWmin using the measured MAQ length and MAQ delay, and set the determined CWmin value as an 802.11 DCF parameter to adjust transmission aggressiveness.

In the above, a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network according to the present invention has been described. Technical effects according to the present invention are as follows.

According to the present invention, by applying a CSMA-based optimal resource allocation method in consideration of interoperability with TCP in a wireless communication network, it is possible to achieve efficiency and fairness of radio resource distribution in a time-variable and asymmetric radio interference situation.

According to the present invention, a radio resource occupancy state of a terminal is directly measured and reflected in a channel access parameter CW (Contention Window), so that radio resources can be equally allocated to all terminals.

According to the present invention, for compatibility with TCP, transmission aggressiveness is adjusted by using the transmission queue delay (MAQ delay), so that the congestion control function of TCP is used when the TCP is operated at the transmission layer. It is possible to solve the problem of not being allocated radio resources.

According to the present invention, by providing a priority scheduling method, quality-of-service (QoS) of a connection requiring high real-time performance such as voice/video communication can be improved.

According to the present invention, it is possible to provide an optimal resource allocation method through design modification of the MAC layer of the 802.11 DCF algorithm, thereby providing interoperability with the standard 802.11 DCF.

Accordingly, when the present invention is applied, radio resources can be equally allocated to all terminals irrespective of the interference situation in a time-variable and asymmetric radio interference situation, thereby increasing the effectiveness of a wireless communication network.

According to the software implementation, not only the procedures and functions described in the present specification, but also design and parameter optimization for each component may be implemented as a separate software module. The software code can be implemented with a software application written in an appropriate programming language. The software code may be stored in a memory and executed by a controller or a processor.

210: Classification
220: Control Queue(CQ)
230: Link Rate Regulator
240: Media Access Queue (MAQ)
250: Link Price Calculator
260: Interface Queue (IFQ)
241: Low Priority Queue (LPQ)
242: High Priority Queue (HPQ)
300: terminal
310: transmitting and receiving unit
320: control unit
330: memory unit
340: user interface unit
350: voice processing unit

Claims (13)

In a CSMA-based optimal resource allocation method considering interoperability with TCP in a wireless communication network, the method is performed by a processor of a terminal, and the method comprises:
In the optimal resource allocation method, the step of performing priority scheduling to guarantee a quality-of-service (QoS) connection;
In the optimal resource allocation method, a media access queue (MAQ) length for determining an occupied state of a radio resource of a terminal and a MAQ delay for compatibility with TCP are determined. Measuring;
Determining CWmin, which is a channel access parameter, using the measured MAQ length and MAQ delay; And
And adjusting transmission aggressiveness by setting the determined CWmin value as an 802.11 DCF parameter. The method of claim 1,
In the step of performing the priority scheduling,
It divides Media Access Queue (MAQ) into Low Priority Queue (LPQ) and Hight Priority Queue (HPQ), and buffers each in Low Priority Queue (LPQ) and Hight Priority Queue (HPQ) according to the priority of transmission packets. Resource allocation method. The method of claim 1,
In the step of measuring the MAQ delay,
A resource allocation method that measures the time a transport packet stays in the Low Priority Queue (LPQ) and Hight Priority Queue (HPQ), respectively. The method of claim 1,
In the step of measuring the MAQ delay,
A resource allocation method for providing transmission fairness between multiple connections by adjusting buffering from Control Queue (CQ) to Media Access Queue (MAQ) according to the measured MAQ delay, and when multiple connections are mixed in the terminal. The method of claim 1,
In the step of measuring the MAQ delay,
According to the measured MAQ delay, performing intra-scheduling to schedule the IFQ in the order of the MAQ delay is large, resource allocation method. The method of claim 1,
In the step of determining the channel access parameter CWmin,
A resource allocation method that weights CWmin according to which queue of the LPQ or HPQ the MAQ packet is a packet. In a terminal that performs a CSMA-based optimal resource allocation method considering interoperability with TCP in a wireless communication network,
A transmission/reception unit configured to transmit or receive a signal including a packet; And
Priority Scheduling is performed to guarantee the quality-of-service (QoS) of the connection,
Measure the transmission queue (Media Access Queue, MAQ) length (MAQ length) for determining the occupancy status of the terminal's radio resource and the MAQ transmission delay (MAQ delay) for compatibility with TCP,
The channel access parameter CWmin is determined using the measured MAQ length and MAQ delay,
And a processor configured to transmit a packet to the physical layer by setting the determined CWmin value as an 802.11 DCF parameter, and adjusting transmission aggressiveness accordingly. The method of claim 7,
The transmission and reception unit,
A terminal, characterized in that the terminal transmits or receives a signal including a packet in the wireless communication network. The method of claim 7,
The processor,
In order to perform the priority scheduling, Media Access Queue (MAQ) is divided into Low Priority Queue (LPQ) and Hight Priority Queue (HPQ),
The terminal, characterized in that buffering each of the Low Priority Queue (LPQ) and Hight Priority Queue (HPQ) according to the priority of the transport packet. The method of claim 7,
The processor,
In order to measure the MAQ delay, it is characterized in that measuring the time that the transport packet stays in the Low Priority Queue (LPQ) and Hight Priority Queue (HPQ), respectively. The method of claim 7,
The processor,
According to the measured MAQ delay, it characterized in that to adjust the buffering from the Control Queue (CQ) to the Media Accdess Queue (MAQ), the terminal. The method of claim 7,
The processor,
According to the measured MAQ delay, the terminal characterized in that to perform intra-scheduling to schedule the IFQ in the order of the MAQ delay is large. The method of claim 7,
The processor,
In order to determine the channel access parameter CWmin, a weight is assigned to CWmin according to which queue of an LPQ or HPQ the MAQ packet is stored.

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