KR101000711B1 - Apparatus and method of scheduling - Google Patents

Abstract

The present invention relates to scheduling of a portable Internet system, and more particularly, to a scheduling method and apparatus for improving data transmission efficiency.

According to an aspect of the present invention, there is provided a scheduling method of a portable internet system, the method comprising: calculating an expected transmission rate for each connection of data of a non-real time service; Calculating an average data rate for each connection; Calculating a scheduling priority value for each connection using the expected transmission rate and the average transmission rate; And scheduling a data burst according to the scheduling priority value for each connection, wherein an expected transmission rate of HARQ connection data among the data of the non-real-time service is determined by reconstruction of data having an error in the current frame. It is characterized by including the radio resource required due to the transmission.

Frame, Scheduling, Proportional Fair, HARQ, Non-HARQ

Description

Scheduling method and apparatus {Apparatus and method of scheduling}

The present invention relates to scheduling of a portable Internet system, and more particularly, to a scheduling method and apparatus for improving data transmission efficiency.

In the portable Internet system, a data transmission order to be transmitted is determined by applying a scheduling method suitable for each service characteristic according to the type of service to be provided. Subsequently, the data size that can be allocated and transmitted is determined according to the state of a wireless channel of data waiting to be transmitted, and a frame is formed and transmitted based on this.

The IEEE 802.16 specification defines unsolicited grant services (UGS), real-time polling services (rtPS), extended real-time polling services (ertPS), non-real-time polling services (nrtPS), and BE services according to QoS requirements of services. Five types of services are classified, including Best Effort Service. Among these, UGS, ertPS, and rtPS services are included in real-time services, and other nrtPS and BE services are included in non-real-time services. These services have QoS parameters such as Minimum Transmission Rate, Maximum Latency, Jitter, and Maximum Sustain Rate.

In this case, scheduling according to a service is generally performed first for a real-time service such as an unsolicited grant service (UGS), a real-time polling service (rtPS), or an extended real-time polling service (ertPS). Scheduling is performed sequentially for non real-time services such as nonreal-time polling service (BE) and best effort service (BE).

There are many factors that affect the data transmission efficiency, and the representative one is scheduling. Scheduling is an algorithm that determines the order of transmission in order to share a given radio resource among multiple users, which is an important factor in determining the quality of service (QoS) and system performance.

In order for a plurality of terminals to be stably provided using a limited radio resource, scheduling must be made so that the plurality of terminals can efficiently occupy the radio channel.

For this reason, scheduling must be able to flexibly control efficiency and fairness while simultaneously considering system efficiency and fairness between users. A representative method in consideration of this is a proportional fair scheduling method (hereinafter referred to as PF scheduling method).

)과, 현재까지 버스트가 할당되어 전송이 이루어진 데이터의 평균 전송률(

)의 비를 계산하고, 이 비율(P_i)이 높은 사용자에게 우선적으로 무선 자원을 할당하는 방식이다. 즉, 현재 시점에서 상대적으로 채널 상태(CINR)가 좋은 사용자에게 우선적으로 무선 자원을 할당하여 시스템 성능을 향상시키는 방식이다.The PF scheduling method does not take into consideration such matters as minimum data rate, delay, and jitter, and thus is suitable for non real-time services such as nrtPS and BE. , The currently available expected rate for all users' terminals (

) And the average rate of transfer of data that has been assigned bursts so far (

), And a radio resource is preferentially allocated to a user having a high ratio P _i . That is, the system performance is improved by allocating radio resources to users having a relatively good channel state (CINR) at the present time.

는 현재까지 전송한 데이터 버스트의 평균량 즉, 평균 전송률을 의미하며,

는 현재 프레임(현재 시점)에 전송 가능할 것으로 예상되는 기대 전송률 이다. 여기서,

는 CINR(Carrier to Interference and Noise Ratio)을 따라 결정된다.In Equation 1, P _i means a data scheduling priority value of the terminal or the connection,

Means the average amount of data bursts transmitted so far, that is, the average data rate.

Is the expected data rate that is expected to be available for transmission in the current frame (current time). here,

Is determined according to the Carrier to Interference and Noise Ratio (CINR).

In addition, the scheduling priority value P _i is changed by adjusting α and β. For example, when α = 1 and β = 0, radio resources are allocated to all users, such as round robin. The scheduling is performed to be equal to, and when α = 0 and β = 1, scheduling is performed to preferentially select a user having a high CINR and allocate resources.

The transmission quality through the wireless channel may be measured by the reliability of receiving the transmitted data at the receiver, and the channel reliability may be defined as a packet error rate (PER). In the portable Internet system, the modulation and coding scheme (MCS) level is determined in consideration of the above-described CINR and packet error rate, and data is transmitted by applying a channel encoding and modulation scheme according to the determined MCS level.

In wireless communication, various factors cause errors in data transmission, resulting in loss of information. In order to solve the data packet error occurring on the wireless channel, a method of correcting an error by retransmitting an error-prone data packet such as a hybrid automatic repeat request (HARQ) is used. There is a problem that fair scheduling is not performed between a connection to which HARQ scheme is applied and a connection to which Non-HARQ scheme is applied.

In the above-described PF scheduling of the prior art, an example will be described for explaining an unfairness of scheduling between a HARQ connection and a non-HARQ connection. An example to be described below assumes a PER of 1% for a non-HARQ connection, a PER of 10% for a HARQ connection, and assumes a CINR gain of 3 dB that can be obtained through HARQ.

For example, if you want to transmit data by setting PER of 1%, Non-HARQ connection will transmit data by applying MCS level satisfying PER of 1%.

On the other hand, HARQ connection transmits data by setting 10% PER, applying MCS level that satisfies 10% PER, and then retransmits to the next frame for 10% data that has an error. As a result, the first transmitted data satisfies the same PER of 1% as the Non-HARQ scheme.

In the above-described PF scheduling method of the prior art, scheduling priority is determined based on a ratio between an expected transmission rate and an average transmission rate according to the CINR value of a connection allocated every frame, and the connection to which the HARQ scheme is applied is an error. Retransmission can be performed on the generated data, so that the higher MCS level can be applied than the non-HARQ method under the same CINR condition. That is, the HARQ connection increases the amount of data that can be transmitted in the current frame as the MCS level increases (expected data rate is higher) than the non-HARQ connection.

As described above, in the PF scheduling of the prior art, even in the same channel state (CINR), the MCS level of the HARQ connection is higher than that of the non-HARQ connection, so that scheduling is concentrated in the HARQ connection when scheduling is performed according to the current CINR. do. This is because scheduling is concentrated on a specific connection (HARQ connection), and there is a problem in that starvation may occur in a specific connection (Non-HARQ connection) along with a disadvantage of not efficiently utilizing radio resources.

In addition, a connection to which the HARQ scheme is applied performs retransmission by allocating a radio resource to the next frame for data having an error during initial transmission. The conventional PF scheduling method requires additional retransmissions. There is a problem in that a fair scheduling is not performed between the HARQ connection and the non-HARQ connection because the radio resource is not considered.

Disclosure of Invention The present invention has been made in view of the above-described problems, and it is an object of the present invention to provide a scheduling method and apparatus for improving data transmission efficiency in a portable Internet system.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and it is an object of the present invention to provide a scheduling method and apparatus capable of performing a fair scheduling between a HARQ connection and a non-HARQ connection in a portable Internet system.

Disclosure of Invention The present invention has been made in view of the above-described problems, and it is a technical object of the present invention to provide a scheduling method and apparatus in consideration of characteristics of data retransmitted in a HARQ connection in a portable Internet system.

A scheduling method according to an embodiment of the present invention for achieving the above object, the scheduling method of a portable Internet system, comprising: calculating an expected transmission rate for each connection for the data of the non-real-time service; Calculating an average data rate for each connection; Calculating a scheduling priority value for each connection using the expected transmission rate and the average transmission rate; And scheduling a data burst according to the scheduling priority value for each connection, wherein an expected transmission rate of HARQ connection data among the data of the non-real-time service is determined by reconstruction of data having an error in the current frame. It is characterized by calculating the radio resources required by the transmission.

A scheduling method according to an embodiment of the present invention for achieving the above object is a scheduling method of non real-time service data including a HARQ connection and a Non-HARQ connection, the target PER Packet Error for each HARQ connection and Non-HARQ connection Setting a Rate, a Carrier to Interference and Noise Ratio (CINR), and a Modulation and Coding Scheme (MCS) level (DUC); Using the amount of valid data in the current frame based on the target PER, CINR, and MCS level (DIUC) and the radio resources required to transmit the valid data, an expected rate is calculated for each connection, and the HARQ connection and the Non-HARQ connection are calculated. Calculating an average transmission rate for each star; Calculating scheduling priority values for the HARQ connection and the non-HARQ connection based on the ratio of the expected data rate and the average data rate; And performing scheduling of the non real-time service data according to the calculated scheduling priority value.

The scheduling apparatus according to the embodiment of the present invention for achieving the above object is to use the MCS level based on the connection-specific data information of the non-real-time service data to calculate the expected data rate of the data in the current frame for each HARQ connection and Non-HARQ connection An expected rate generation unit for generating an expected rate including a radio resource required due to retransmission of data having an error in the current frame for the HARQ connection; An average rate generation unit for calculating an average rate up to the current frame for each connection; And a PF scheduler that performs scheduling for each connection of the non-real-time service data according to a scheduling priority value for each connection based on the expected transmission rate for each connection from the expected rate generation unit and the average transmission rate for each connection from the average rate generation unit. Characterized in that.

The present invention according to the embodiment provides an effect that can improve the data transmission efficiency in a portable Internet system that supports HARQ.

The present invention according to the embodiment provides an effect that can prevent the scheduling priority is concentrated in a specific connection in a portable Internet system that supports HARQ.

The present invention according to the embodiment provides the effect of performing a fair scheduling between the HARQ connection and the Non-HARQ connection in a portable Internet system that supports HARQ.

The present invention according to the embodiment provides an effect of improving the data transmission efficiency by allocating a radio resource through scheduling in consideration of the characteristics of the re-transmitted data of the HARQ connection in a portable Internet system supporting HARQ.

Prior to the description with reference to the drawings, in the following description, the base station (BS) is a transmitter and the mobile station (MS) is based on data transmission of the downlink (DL). However, this is merely exemplary and the roles of the base station and the terminal are switched to each other, so that the configuration and scheduling method of the present invention can be equally applied to data transmission of uplink (UL), in which the terminal is a transmitter and the base station is a receiver.

The present invention relates to a scheduling method and apparatus for improving data transmission efficiency in a portable Internet system supporting HARQ. Hereinafter, the components related to scheduling in the configuration of a base station will be described in detail. Detailed description of the components will be omitted. First, the scheduling performed in the base station will be briefly described. Hereinafter, the scheduling apparatus and scheduling method of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a base station including a scheduling apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a base station 100 including a scheduling apparatus 200 according to an embodiment of the present invention may determine a radio resource (wireless channel) allocated to each terminal based on feedback information transmitted from a terminal. In performing the scheduling, the connection of the transmitted data is classified, and the expected transmission rate is calculated according to the connection of each data, and the scheduling is performed so that the radio resources can be equally allocated to the non-HARQ connection and the HARQ connection. To perform.

In this case, the scheduling apparatus 200 finds a channel having an optimal performance for each terminal, and then assigns a channel having the optimal performance to the terminal. In addition, in consideration of the characteristics of the non-HARQ connection and HARQ connection, the expected transmission rate is calculated at the present time, and scheduling is performed based on the calculated expected transmission rates. After that, the data burst is allocated to the frame according to the scheduling and transmitted to the terminal.

To this end, the base station 100, as shown in Figure 1, the band signal processor 110, the transmitter 120, the receiver 130, the antenna 140, the map message generator 150, burst allocation unit ( 160 and the scheduling device 200.

The receiver 130 converts a signal received through the antenna 140 into a digital signal. For example, the receiver 130 removes and amplifies the noise from the above-described signal for data reception by the base station 100, down converts the amplified signal into a baseband signal, and digitizes the down-converted baseband signal.

The band signal processor 110 extracts data bits from the digitized signal from the receiver 120 to perform demodulation, decoding, and error correction. The received information is transmitted to an adjacent wired / wireless network (not shown) through an interface (not shown), or transmitted to terminals served by the base station 100 through a transmission path. In addition, the band signal processor 110 encodes input data and control information and outputs the encoded data and control information to the transmitter 120.

The transmitter 120 modulates the burst of data allocated by the burst allocator 160, that is, the encoded voice, data, or control information into a carrier signal having a desired transmission frequency or frequencies, and modulates the modulated carrier signal suitable for transmission. Amplifies to a level and propagates through the antenna 140 to the air. Information on the transmitted data burst is defined in the downlink and uplink map messages DL_MAP_IE and UL_MAP_IE of the map message generated by the map message generator 150.

The map message generator 150 generates a map information element MAP_IE including information on allocation of data allocated in the frame according to the scheduling of the scheduling apparatus 200. That is, the downlink map (DL-MAP_IE) message and the uplink map (UL-MAP_IE) message are created in the map message area of the frame based on the scheduling information of the data burst. The map message generated by the map message generator 150 is allocated to the map message area of the frame.

Referring to FIG. 2, an OFDMA frame of a portable Internet system includes a map message area including a configuration information of a frame, a downlink (DL_Link) subframe, and an uplink (UL_Link) subframe.

In general, downlink transmission starts with one preamble symbol, an FCH and downlink map (DL_MAP) message, and data burst (# 1 to #n) symbols, and uplink transmission starts with control symbol transmission. TTG and RTG, which is a guard time for distinguishing uplink and downlink transmission times, are allocated between the downlink and uplink in the middle and at the end of the frame.

The data packet transmitted to the terminal is modulated and encoded in burst units, and a data burst may be configured for each connection of each terminal and allocated to a downlink (DL_Link) subframe. In this case, the data burst allocated to the downlink (DL_Link) subframe includes data having the same channel modulation and coding rate (MCS level). In addition, a data burst may be configured with data of a plurality of terminals having the same channel modulation and coding rate (same MCS level) and allocated to a downlink (DL_Link) subframe.

The map message generated by the map message generator 150 is composed of a downlink map (DL_MAP) message for downlink and an uplink map (UL_MAP) message for uplink and is allocated to a map message area of a frame.

The downlink map (DL_MAP) message includes information indicating which terminal data are downlink data bursts transmitted from the base station 100 and in which region the data burst of a specific terminal is located in the downlink frame. In addition, the uplink map message includes information indicating in which region the data burst of a specific terminal is located in the uplink bursts transmitted by the terminals in the uplink frame.

The downlink map message of the map message includes a downlink map information element (IE) in which information on each data burst is defined. Here, the downlink map information element includes the modulation level of the data burst, the starting point (symbol offset and subchannel offset) of the data burst, the length of the data burst (number of symbols and the number of subchannels), and terminal information to receive the data burst. Included.

That is, the map message generating unit 150 is configured by the scheduling apparatus 200 and downlink map information element (DL_MAP_IE) and uplink map information of the information of the respective data bursts allocated to the frame by the burst allocator 160. It is included in element (UL_MAP_IE) to create a map message. In this case, the map message generator 150 may arrange the map information IEs of the corresponding data bursts in the map message in the order in which the data bursts are allocated.

The burst allocator 160 allocates the data burst transmitted to each terminal to the downlink subframe and the uplink subframe, respectively, according to the scheduling result of each connection from the scheduling apparatus 200.

Herein, the size of the data burst to be allocated is determined in consideration of the size of the data to be transmitted, the channel state, and the like, and the data burst to be allocated is allocated to a two-dimensional region defined by time and frequency in each subframe region.

The burst allocator 160 sequentially allocates downlink data bursts based on the symbol offset. In this case, the downlink data burst may allocate the data burst in a two-dimensional area in the vertical and horizontal directions.

Here, the meaning of allocating data bursts in the vertical direction is to allocate data bursts in a direction in which subchannels increase in a predetermined symbol interval, and after allocating data bursts for all subchannels in a predetermined symbol interval is completed. This means that data bursts are sequentially allocated from the first subchannel of the next symbol period.

On the other hand, the meaning of allocating the data burst in the horizontal direction means that the data burst is allocated in the direction in which the symbol increases in the interval of the predetermined sub-channel, and after the allocation of the data burst for all symbols in the interval of the predetermined channel, the next channel This means that data bursts are sequentially allocated from the first subchannel of the interval.

Subsequently, the scheduling apparatus 200 performs scheduling by determining which rule to allocate available radio resources of the base station 100 to each terminal. The scheduling apparatus 200 allocates the data of the non-HARQ connection and the data of the HARQ connection in all burst regions of the uplink subframe and the downlink subframe of the current frame for data transmission and reception of each user every frame. Identify possible queues and manage the allocation of subchannels to the data of each connection.

The scheduling apparatus 200 first performs scheduling by dividing the terminal and the connection, and calculates an expected transmission rate for each connection to be transmitted to each terminal by distinguishing between a terminal supporting HARQ and a terminal not supporting HARQ. Then, as shown in the equation (1) on the basis of the expected transmission rate calculation, it generates a scheduling priority value (P _i) of data. Then, it performs scheduling based on the generated scheduling priority value (P _i).

Here, the scheduling apparatus 200 according to an embodiment of the present invention generates an expected data rate reflecting the data characteristics of the HARQ connection, that is, the radio resource required for the data to be retransmitted, thereby generating a radio resource between the HARQ connection and the non-HARQ connection. Scheduling is done so that it is allocated evenly.

To this end, the scheduling apparatus 200 according to an embodiment of the present invention, as shown in FIG. 3, the data information checking unit 210, the MCS setting unit 220, the average rate generating unit 230, and the expected rate generating The unit 240 includes a proportional fair scheduler 250 and a PER setting unit 260.

First, the data information checking unit 210 checks a map information element (IE) of data to be transmitted from a base station 100 to a plurality of terminals, a class of service, transmission information of data, and CINR of a subchannel. Here, the transmission information of the data refers to transmission information of data for each connection, and includes connection information (information on HARQ connection or non-HARQ connection) of the transmitted data and information on whether it is the first transmission or retransmission. . In addition, each connection includes information on the transmission data transmitted up to now.

The PER setting unit 260 sets a PER of data for each connection to be transmitted based on the input data transmission information. In this case, the PER setting unit 260 may set a different PER for the data of the connection to which the HARQ method is applied and the data of the connection to which the HARQ method is not applied. For example, a PER of 1% or less can be set for data of a non-HARQ connection, and a PER of 10% can be set for data of a HARQ connection.

Here, setting the PER of the HARQ connection higher than the PER of the non-HARQ connection utilizes the advantages of the characteristics of the HARQ connection. The HARQ connection sets the PER higher so that even if an error occurs during transmission, the error is generated. This is because the error can be corrected by performing retransmission.

The MCS setting unit 220 sets the MCS level for each connection using the data information provided from the data information checking unit 210 and the CINR value according to the target PER set by the PER setting unit 260. Here, the HARQ connection and the non-HARQ connection may have different MCS level values as described above even in the same channel state (CINR). Accordingly, the MCS setting unit 220 may set a different MCS level for the data of the HARQ connection and the data of the Non-HARQ connection.

Specifically, in the case of HARQ connection, if the error is corrected through Chase Combining for the data to be retransmitted, a gain of 3 dB is generally obtained compared to the data not to be retransmitted. A high MCS level corresponding to the gain of 3 dB obtained can be applied.

For example, with reference to FIG. 4, when a CINR for an arbitrary channel is 10 dB and data is to be transmitted through a channel having a CINR of 10 dB, a DIUC (Downlink Interval Usage Code) value corresponds to 3, so DIUC According to the value (3), the highest applicable MCS level is an MCS level having a modulation scheme of 16QAM and a 2/3 coding rate.

Here, when the connection of the data to be transmitted is HARQ, a 10% PER is applied to obtain a gain of 3 dB in the same CINR as the non-HARQ connection as described above, and the DIUC value corresponds to 4. Therefore, according to the DIUC value (4), it is possible to apply a modulation scheme of 16QAM and an MCS level having a 3/4 coding rate.

As a result, when comparing the data transmission rates of HARQ connections and non-HARQ connections with the same CINR, the data of HARQ connections with a high PER is applied to a higher MCS level than the data of a non-HARQ connection with a low PER. As a result, this may increase the amount of data transmitted at the same time.

The DIUC value and MCS level for each CINR illustrated in FIG. 4 are examples for clarity of understanding according to an embodiment of the present disclosure. The DIUC value and MCS level for each CINR may vary depending on the configuration and characteristics of a communication system. Can be.

In addition, the MCS setting unit 220 may apply the same MCS level to both connections when the HARQ connection and the non-HARQ connection have different channel states.

For example, if the CINR for a channel of a non-HARQ connection with 1% PER is 10 dB and the data is to be transmitted through a channel having a CINR of 10 dB, the DIUC value corresponds to 3, so the DIUC value (3 ) Is applied to the modulation scheme of 16QAM and MCS level having 2/3 coding rate.

If the CINR of the channel of the HARQ connection is 6 dB, the MCS level should be applied according to the DIUC value (2) corresponding to the CINR of 6 dB, but the HARQ connection retransmits the next frame with respect to the data having an error. You can set a higher PER (eg 10% PER) than a non-HARQ connection.

In this case, the HARQ connection can gain 3dB by setting a higher target PER (eg, 10% PER) than the non-HARQ connection, so that the modulation scheme of 16QAM corresponding to the DIUC value 3 and 2/3 MCS levels having a coding rate can be applied.

As a result, the same MCS level can be applied to the HARQ connection and the non-HARQ connection having different channel states (CINR). Information on the MCS level of the connection-specific data set by the MCS setting unit 220 is provided to the expected data rate generation unit 240.

The average rate generating unit 230 generates average rate information by calculating an average rate up to now based on the rate information of data allocated to a frame for each connection of a plurality of terminals every frame. The average rate information generated by the average rate generator 230 is provided to the PF scheduler 250.

The expected rate generation unit 240 calculates the amount of data that can be transmitted for each terminal and connection at the present time by using the data information from the data information checking unit 210 and the MCS level information from the MCS setting unit 220. Then, based on the calculated amount of data, an expected transfer rate of data is generated.

Here, the expected rate generation unit 240 calculates the expected rate for each terminal and connection, and calculates the MCS level according to the set target PER and CINR, and takes into account the radio resources required to transmit a certain amount of data. do.

First, the expected transmission rate of a non-HARQ connection is determined by the amount of valid transmission data at the present time. The amount of valid transmission data (SpEff _non-HARQ ) at the present time for the non-HARQ connection is expressed by Equation 2 below. Can be represented as:

Assuming a PER of 1% of the non-HARQ connection in Equation 2, since 99% of the transmitted data is data transmitted without error, the non-HARQ connection is reflected to the non-HARQ connection. The amount of valid transmission data at the present time can be calculated.

Here, the PER is the ratio of the error can occur in the total data transmitted, the MCS level represents the modulation and coding scheme of the data means a byte of data that can be transmitted per slot (slot).

Accordingly, based on Equation 2, the non-HARQ connection calculates the expected data rate through the amount of data transmitted without error compared to the radio resources required for data transmission in the current frame.

Expected data rate is a ratio of radio resources allocated to non-HARQ connections in the current frame, ie, how much data (bytes) can be transmitted through slots that can be allocated to the current frame. As this is applied, the expected transmission rate becomes larger.

Subsequently, the expected transmission rate of the HARQ connection is determined by the amount of valid transmission data at the present time (current frame), the amount of data retransmitted in the next frame, and the radio resource required for data transmission.

Specifically, the amount of valid transmission data SpEff _HARQ at the present time of the HARQ connection may be expressed as in Equation 3 below.

In Equation 3, n corresponding to the index of "PER _HARQ " is the number of data transmissions, and when n is 0, it means the first transmission, and as n increases, the number of retransmissions increases. Accordingly, n is defined as 0 for the first transmission in the current frame.

As shown in FIG. 5, when the PER of the HARQ connection is 10%, since 90% of the total data allocated to the current frame and transmitted are data transmitted without error, the MCS level is reflected here. It is possible to calculate the amount of valid transmission data at the current time of the connection that does not support HARQ.

Here, since the HARQ connection retransmits the next frame with respect to 10% of data in which an error occurs, the amount of valid transmission data (SpEff _HARQ ) considering _{retransmission} increases n to 1 in Equation 3 above. It can be expressed as Equation 4 below.

As shown in Equation 4, when the amount of valid transmission data of the HARQ connection considering retransmission is calculated, the same result as in the Non-HARQ connection according to Equation 2 is obtained. That is, the HARQ connection transmits data in the first frame by setting the PER to 10%, and then retransmits the second frame with respect to 10% of the data in which an error occurs, thereby, in the current frame (first frame). By setting the PER to 1%, you get the same amount of valid data as a non-HARQ connection that sends data.

Here, in order to perform the scheduling of the HARQ connection and the non-HARQ connection evenly according to the purpose of PF scheduling, the expected transmission rates of the two connections must be compared in the same criteria.

However, when the target PER of the HARQ connection and the non-HARQ connection are viewed in the current frame (first frame), the PERs are different from each other as described above. That is, since the criteria for the expected data rates between the two connections are different from each other, scheduling cannot be made fair.

Here, considering the same criterion from the perspective of PER, as shown in FIG. 5, in order for the HARQ connection to satisfy the PER 1% as in the non-HARQ connection, as shown in FIG. 5, an error occurs in the current frame (first frame). Retransmission should be performed on the next frame (second frame) with respect to the data. Therefore, for the HARQ connection, the expected transmission rate should be calculated in consideration of the radio resource required for retransmission of data in the next frame (second frame).

That is, for fair scheduling between the HARQ connection and the non-HARQ connection, not only the radio resource required for the current frame but also the radio resource required due to data retransmitted in the next frame should be considered.

Here, the expected transmission rate of the HARQ connection considering the radio resource required due to retransmitted data may be represented by Equation 5 below.

The expected rate is how much data (sometimes) through the radio resources allocated to HARQ connections in the current frame, that is, the slots allocated to the current frame (first frame) and the slots allocated to retransmission data in the next frame (second frame). Byte) can be transmitted, so the lower the PER is applied to the higher MCS level, the higher the expected data rate will be.

Through Equation 3 to 5, the expected transmission rate of the HARQ connection calculated by the expected transmission rate generation unit 240 can be summarized as in Equation 6 below. In this case, the calculated expected transmission rate is taken into account the radio resources required to perform the retransmission, the expected transmission rate of the HARQ connection that satisfies the PER 1%, the same as the non-HARQ connection for the first data transmitted through the retransmission to be.

In Equation 6, "HARQ" of the denominator is a radio resource required for data transmission of the HARQ connection in the current frame (first frame), and "HARQ _RETX " is retransmission of the HARQ connection in the next frame (second frame). Represents radio resources consumed by data. In addition, the numerator indicates the amount of valid data of the HARQ connection in the current frame (first frame) and the amount of valid data of the HARQ connection in which retransmission is performed in the next frame (second frame).

The above-described expected rate generation unit 240 calculates an expected rate of HARQ connection in consideration of radio resources required by retransmitting data having an error. This ensures fair scheduling between non-HARQ connections and HARQ connections. Information on the expected data rate for each terminal and connection generated by the expected data rate generator 240 is provided to the PF scheduler 150.

As described above, the PF scheduler 150 determines the average amount of data bursts transmitted to each connection from the average rate generator 230, that is, the average rate and the expected rate for each connection from the expected rate generator 340. The scheduling priority value P _i for each connection is calculated through the ratio, and scheduling is performed in the order of the connections having the largest scheduling priority value.

The scheduling apparatus 200 according to an exemplary embodiment of the present invention including the above-described configuration calculates a scheduling priority value in consideration of radio resources required due to retransmission of data having an error in a HARQ connection. Ensure fair scheduling between the HARQ connection and the HARQ connection. This prevents the scheduling priority from being concentrated in a specific connection and improves data transmission efficiency in a portable Internet system supporting non-HARQ connection and HARQ connection.

In the above-described embodiment, the scheduling apparatus 200 is described as being included in the base station 100 as an independent component, but these components may be implemented as one integrated component in the base station 100.

Hereinafter, a scheduling method according to an exemplary embodiment of the present invention will be described with reference to FIGS. 6 to 10.

Prior to the description with reference to the drawings, a scheduling method according to an embodiment of the present invention relates to scheduling of a connection of a non-real time service such as a non-real time polling service (nrtPS) and a best effort service (BE) service. Scheduling will be briefly described.

6 is a flowchart illustrating a scheduling method according to an exemplary embodiment of the present invention.

Referring to FIG. 6, a service class of a data burst to be allocated to a frame for each connection of a plurality of terminals is classified according to a service class provided by a base station, and data of each connection of the plurality of terminals is determined according to a classification result of the service class. The scheduling order is determined (S100).

Here, in order to determine the scheduling order, scheduling is performed on data corresponding to a real-time service first, and then scheduling is performed on data of a non-real-time service. The scheduling order of the terminals is determined according to a predetermined ranking method in consideration of the channel state of each terminal and the service class of data to be allocated to each terminal.

According to a predetermined scheduling rank determination method, uplink and downlink are classified for each of a plurality of terminals to perform scheduling for each data burst corresponding to real-time service in the burst region of the uplink subframe and the downlink subframe (S110). ).

In this case, an uplink map information element UL_MAP_IE and a downlink map information element DL_MAP_IE, which define information about data bursts allocated to burst regions of an uplink subframe and a downlink subframe, are uplinked and downlinked for each user equipment. It is assigned to the link map message area.

Thereafter, a queue for storing data to be transmitted for each connection of the non real-time service is checked (S120). Here, the queue stores data of a non-real-time service to be scheduled. If the queue is empty, it means that there is no data of a non-real-time service to be scheduled in the current frame (this frame). In this case, it means that there is non-real time data to be scheduled in the current frame.

When the queue is empty, it means that there is no data of the non-real time service to be scheduled. In this case, the scheduling method according to the embodiment of the present invention is not applied. For example, if there is data of a service.

Thereafter, the information on the map information element MAP_IE and the data to be transmitted are checked in the downlink map message region DL_MAP and the uplink map message region UL_MAP (S130).

Thereafter, the HARQ connection and the non-HARQ connection are distinguished from the data of the non real-time service stored in the queue by using the confirmation result of S130 (S140).

Thereafter, PER for each connection is set for each of the HARQ connection and the non-HARQ connection (S150). In this case, the non-HARQ connection does not perform retransmission even if an error occurs during the transmission of data, so a low PER (for example, 1% or less) is set to increase the reliability of the transmitted data. On the other hand, when an error occurs during data transmission, the HARQ connection may retransmit the error-prone data, thus setting a higher PER (eg, 10%) than the non-HARQ connection. .

Thereafter, the MCS level is set for each connection based on the PER and channel state (CINR) set for each connection (S160).

Subsequently, an expected transmission rate for each connection is calculated based on the scheduling factors PER, MCS, and CINR set in S150 and S160 (S170).

Methods of calculating the expected transmission rates per connection based on the scheduling factors PER, MCS, and CINR in S170 will be described in detail with reference to FIGS. 7 to 10.

First, as shown in FIG. 7 and FIG. 8, the first method calculates factors of PF scheduling, as shown in FIG. 8 on the basis of CINR, in order to calculate an expected transmission rate per connection (S300).

As described above, the PF scheduling method basically determines the priority of scheduling according to the CINR of the current time point. Since the PER set between the HARQ connection and the non-HARQ connection is different, the CINR and the MCS level are set between the two connections. The DIUC value that is the reference to is also different.

The present invention according to the embodiment calculates the factors (DIUC, PER) of the PF scheduling of the two connections based on the CINR, as shown in Figure 8, for fair scheduling between HARQ connection and Non-HARQ connection, Based on the amount of valid transmission data of the HARQ connection and the non-HARQ connection is calculated (S310). In this case, the Non-HARQ connection calculates the amount of valid transmission data of the connection according to Equation 2, and the HARQ connection calculates the amount of effective transmission data of the connection according to Equations 3 and 4.

Thereafter, a radio resource required for transmitting the effective amount of transmission data calculated in S310 for each connection is calculated (S320). In this case, the HARQ connection retransmits data in which an error occurs among data transmitted in the current frame (first frame) to the next frame (second frame). Therefore, the radio resources required for the transmission of the effective transmission data amount calculated in the S310 not only the radio resources required in the current frame but also the radio resources required in the next frame, that is, the radio resources required for retransmission of the error-prone data. Include it in the resource.

Subsequently, an expected transmission rate for each connection is calculated based on the ratio of the effective transmission data amount calculated in S310 and the radio resource calculated in S320 (S330).

9 and 10, the second method calculates factors of PF scheduling as shown in FIG. 10 on the basis of the MCS level (DIUC) in order to calculate an expected transmission rate per connection (S400). .

As described above, the PF scheduling method basically determines the scheduling priority according to the CINR of the current time point. Since the PER set between the HARQ connection and the non-HARQ connection is different, the setting of the CINR and the MCS level is performed between the two connections. The reference DIUC value is also different.

According to an embodiment of the present invention, for fair scheduling between a HARQ connection and a non-HARQ connection, as shown in FIG. 10, factors of PF scheduling of two connections (CINR, PER) based on an MCS level (DIUC) are determined. The amount of valid transmission data of the HARQ connection and the non-HARQ connection is calculated based on the calculation.

The MCS level DIUC having the same PER as the HARQ connection and the non-HARQ connection is detected from the factors of the PF scheduling calculated based on the MCS level DIUC calculated in S400 (S410).

Thereafter, it is checked whether the MCS level (DIUC) of the HARQ connection and the non-HARQ connection having the same PER is the same (S420).

As a result of checking in S420, when the MCS level (DIUC) of the HARQ connection and the non-HARQ connection is the same, the expected transmission rate is calculated by applying the CINR and the PER at this time (S430).

On the other hand, if the check result of S420, if the MCS level (DIUC) of the HARQ connection and the non-HARQ connection is not the same, the PER of the HARQ connection is adjusted (S440). At this time, the PER of the HARQ connection is adjusted to a value equal to the PER of the Non-HARQ connection by retransmitting the data in which the error occurs.

Subsequently, an expected data rate is calculated for each HARQ connection and non-HARQ connection. In calculating the expected data rate, the non-HARQ connection calculates the amount of valid transmission data of the connection according to Equation 2, and the HARQ connection calculates the amount of effective transmission data of the HARQ connection according to Equations 3 to 6. do.

Thereafter, a radio resource required to transmit the calculated effective transmission data amount for each connection is calculated. In this case, the HARQ connection transmits data by applying the factors (CINR, PER, MCS level) of the PF scheduling, as in the first method described above, and then uses the radio resources required due to retransmission of an error-prone data. Consider together.

Subsequently, an expected data rate is calculated by considering the radio resources required for retransmission for the HARQ connection through the ratio of the calculated effective transmission data amount and the radio resources required for the transmission of the effective transmission data amount (S450).

In the scheduling method according to an exemplary embodiment of the present invention, an expected transmission rate that is a basis for determining scheduling priority is calculated through the methods illustrated in FIGS. 7 to 10.

6, after S170, the average transmission rate of the data transmitted so far is calculated for each connection (S180).

Thereafter, the scheduling priority value is calculated based on the ratio of the expected data rate calculated in S170 to the average data rate calculated in S180 (S190).

Thereafter, PF scheduling is performed on the data of the non-real time service based on the scheduling priority value calculated in S190 (S200).

As described above, the scheduling method according to the embodiment of the present invention calculates a scheduling priority value in consideration of radio resources required due to retransmission of data having an error in a HARQ connection, and thus, between a non-HARQ connection and a HARQ connection. Ensure fair scheduling is achieved. By doing so, it is possible to prevent scheduling priorities from being concentrated in a specific connection and improve data transmission efficiency in a portable Internet system supporting HARQ.

The above-described scheduling method may be implemented in the form of a program that can be executed using various computer means. A program for performing the scheduling method may be a recording medium (eg, a hard disk, A recording medium such as a CD-ROM, a DVD, a ROM, a RAM, or a flash memory. It also includes those implemented in the form of carrier waves (eg, transmission over the Internet). The computer-readable recording medium may be distributed and formed in a computer system connected via a network.

Configuration and operation as described above is not limited to the claims of the present invention as an embodiment, and various changes and modifications are possible within the scope of not changing the technical spirit of the present invention in the field to which the present invention belongs. It is obvious to those who are engaged.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Accordingly, the above detailed description should not be interpreted as limiting in all aspects and should be considered as illustrative. The scope of the invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the invention are included in the scope of the invention.

1 is a diagram illustrating a base station including a scheduling apparatus according to an embodiment of the present invention.

2 is a diagram illustrating a frame structure of a mobile internet system.

3 is a diagram illustrating a configuration of a scheduling apparatus according to an embodiment of the present invention.

4 is a diagram illustrating DIUC values and MCS levels for each CINR.

5 is a diagram illustrating a data transmission method of HARQ connection.

6 is a flowchart illustrating a scheduling method according to an embodiment of the present invention.

7 is a flowchart illustrating a first method of calculating an expected rate of HARQ connection.

8 is a diagram illustrating DIUCs and PERs of HARQ connections and non-HARQ connections for each CINR.

9 is a flowchart illustrating a second method of calculating an expected data rate of a HARQ connection.

10 is a diagram illustrating CINRs and PERs of HARQ connections and non-HARQ connections for each DIUC.

<Explanation of symbols for the main parts of the drawings>

100: base station 110: band signal processing unit

120: transmitter 130: receiver

140: antenna 150: map message generation unit

160: burst allocation unit 200: scheduling device

210: map message confirmation unit 220: MCS setting unit

230: average rate generator 240: expected rate generator

250: PF scheduler

Claims (19)

In the scheduling method of a portable Internet system, Calculating an expected transmission rate per connection for data of the non-real time service; Calculating an average data rate for each connection; Calculating a scheduling priority value for each connection using the expected transmission rate and the average transmission rate; And Scheduling a data burst according to the scheduling priority value of each connection; The expected transmission rate for each connection is calculated using a PER and MCS level (DIUC) for each connection calculated based on a CINR having a HARQ (non-HARQ) connection and a non-HARQ connection of the non real-time service, or The expected transmission rate for each connection is calculated using PER and CINR per connection calculated based on the MCS level (DIUC) in which the HARQ connection and the non-HARQ connection have the same value. The expected transmission rate of the HARQ connection data is calculated, including the radio resources required due to the retransmission of the data error occurs in the current frame. The data transmission rate of claim 1, wherein the expected rate of non-HARQ connection data is among the data of the non-real time service. The method of claim 1, characterized by calculating the ratio of the amount of valid data that can be transmitted in the current frame and the radio resources required to transmit the valid data of the current frame. The method of claim 2, wherein the scheduling priority value of the non-HARQ connection data is And calculating the ratio between the expected data rate of the non-HARQ connection data and the average data rate up to the current frame. The method of claim 1, wherein the expected rate of HARQ connection data of the non-real time service data is The method of claim 1, further comprising calculating the first valid data amount that can be transmitted in the current frame and the second valid data amount that is obtained through retransmission in the next frame. The method of claim 1, wherein the scheduling priority value of the HARQ connection data is And calculating the ratio between the expected data rate of the HARQ connection data and the average data rate up to the current frame. In the scheduling method of non real-time service data including a HARQ connection and a Non-HARQ connection, Setting a target Packet Error Rate (PER), a Carrier to Interference and Noise Ratio (CINR), and a Modulation and Coding Scheme (MCS) level (DIUC) for each HARQ connection and a Non-HARQ connection; Using the amount of valid data in the current frame based on the target PER, CINR, and MCS level (DIUC) and the radio resources required to transmit the valid data, an expected transmission rate of a HARQ connection and a non-HARQ connection is calculated, and the HARQ Calculating an average data rate of the connection and the non-HARQ connection; Calculating scheduling priority values for the HARQ connection and the non-HARQ connection based on the ratio of the expected data rate and the average data rate; And And scheduling the non-real time service data according to the calculated scheduling priority value. The expected transmission rate is calculated for each connection by using a PER and MCS level (DIUC) per connection calculated based on a CINR in which the HARQ connection and the non-HARQ connection have the same value, or the HARQ connection and the non-HARQ connection have the same value. A scheduling method, characterized in that the expected transmission rate is calculated for each connection using PER and CINR for each connection calculated based on the MCS level (DIUC) having a value. 7. The method of claim 6, wherein the expected transmission rate of the HARQ connection is And calculating a radio resource required due to retransmission of data having an error in the current frame. 7. The method of claim 6, wherein calculating the expected data rate of the HARQ connection Calculating a PER and MCS level (DIUC) for each HARQ connection and non-HARQ connection based on a CINR having the same value as the HARQ connection and the non-HARQ connection; Calculating a valid data amount of a current frame and a radio resource required to transmit valid data of the current frame based on the PER and MCS level (DIUC) for each HARQ connection and a non-HARQ connection; And Calculating an amount of retransmission valid data obtained by performing retransmission of the HARQ connection and a radio resource required for transmission of the retransmission valid data. 7. The method of claim 6, wherein calculating the expected data rate of the HARQ connection Calculating PER and CINR for each HARQ connection and non-HARQ connection based on an MCS level (DIUC) in which the HARQ connection and the non-HARQ connection have the same value; Calculating a valid data amount of a current frame and a radio resource required to transmit valid data of the current frame based on the PER and CINR for each HARQ connection and a non-HARQ connection; And Calculating an amount of retransmission valid data obtained by performing retransmission of the HARQ connection and a radio resource required for transmission of the retransmission valid data. Generates an expected data rate of data in the current frame for each HARQ connection and non-HARQ connection by using the MCS level based on the connection-specific data information of the non-real-time service data, but generates an error in the current frame for the HARQ connection. An expected data rate generator for calculating an expected data rate including radio resources required by retransmission of the data; An average rate generation unit for calculating an average rate up to the current frame for each connection; And A PF scheduler that performs scheduling for each connection of the non-real time service data according to a scheduling priority value for each connection based on the expected transmission rate for each connection from the expected rate generation unit and the average transmission rate for each connection from the average rate generation unit. and, The expected rate generation unit calculates an expected rate of the HARQ connection by using a PER and MCS level (DIUC) for each connection calculated based on a CINR in which the HARQ connection and the non-HARQ connection have the same value, or the HARQ connection and the HARQ connection. The non-HARQ connection scheduling apparatus for calculating the expected transmission rate of the HARQ connection using the PER and CINR per connection calculated based on the MCS level (DIUC) having the same value. The method of claim 10, And a data information checking unit for identifying the map information elements and the data information of each non-real-time service data and generating data information for each connection. The method of claim 10, And a PER setting unit configured to set a PER for each connection by using the data information. The method of claim 10, And an MCS setting unit configured to set an MCS level for each connection by using the data information. 12. The apparatus of claim 10, wherein the expected rate generator And an expected transmission rate of the non-HARQ connection data based on a ratio of an amount of valid data that can be transmitted in a current frame and a radio resource required to transmit valid data of a current frame. 12. The apparatus of claim 10, wherein the expected rate generator The expected transmission rate of the HARQ connection data is calculated using the first effective data amount that can be transmitted in the current frame and the second effective data amount that is obtained by retransmission in the next frame. 11. The method of claim 10, wherein the PF scheduler And a scheduling priority value for each connection is calculated based on a ratio between the expected data rate of the data for each connection and the average data rate for the current frame for each connection. 12. The apparatus of claim 10, wherein the expected rate generator Calculate PER and MCS level (DIUC) for each HARQ connection and non-HARQ connection on the basis of the CINR where the HARQ connection and the non-HARQ connection have the same value; And a radio resource required for transmitting the valid data amount of the current frame and the valid data of the current frame based on the calculated PER and MCS level (DIUC) for each connection. 12. The apparatus of claim 10, wherein the expected rate generator A PER and CINR for each HARQ connection and a non-HARQ connection are calculated based on an MCS level (DIUC) in which the HARQ connection and the non-HARQ connection have the same value. And a radio resource required for transmitting the valid data amount of the current frame and the valid data of the current frame based on the calculated PER and CINR for each connection. 12. The apparatus of claim 10, wherein the expected rate generator And a retransmission valid data amount obtained by performing retransmission of the HARQ connection and a radio resource required for transmission of the retransmission valid data.

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