WO2010077023A2 - Apparatus and method for scheduling in a broadband radio communication system - Google Patents

Abstract

The present invention relates to an apparatus and a method for scheduling multiple bursts containing a collaborative spatial multiplexing (CSM) burst and a non-CSM burst in a broadband radio communication system. The method comprises the steps of packet-scheduling an uplink data packet corresponding to the bandwidth request from a terminal such that the packet is allocated to either the CSM burst or the non-CSM burst, determining a modulation and coding scheme (MCS) level and a transmission power level corresponding to the packet-scheduled uplink data packet using the maximum number of bytes for each MCS level in accordance with the types of the multiple bursts calculated for the terminal, determining a transmission power offset in accordance with the type of the burst to which the packet-scheduled uplink data packet is allocated using the MCS level and the power transmission level determined in the previous step, and generating MAP information for the terminal, containing burst allocation information of the uplink data packet and information of the transmission power offset determined in the previous step.

Description

Scheduling apparatus and method in broadband wireless communication system

The present invention relates to a scheduling method and apparatus in a broadband wireless communication system, and more particularly, to a scheduling apparatus for an uplink (UL) burst in a broadband wireless communication system. And to a method.

In the next generation wireless communication system, methods for providing users with services of various quality of service (QoS) (hereinafter referred to as 'QoS') having a high transmission rate through limited radio resources have been proposed. .

As one of the methods for efficiently using the radio resources, there is a multiple input multi output (MIMO) technology in which a channel is spatially separated and communicated using a plurality of transmit antennas and receive antennas. By using the same time and frequency resources using the multiple input / output technology, by transmitting and receiving different signals by spatially separating each channel of the N antennas, the communication system to which the multiple input / output technology is applied has a maximum of N compared to a single antenna system. Double channel capacity gain can be obtained.

On the other hand, as a technique applied to the multiple input and output technology, a cooperative spatial multiplexing (CSM: Collaborative Spatial Multiplexing, constituting a virtual multiple input and output environment by considering a plurality of terminals in a UL frame as a single terminal using a plurality of antennas) A technique called 'CSM' has been proposed. Specifically, in the CSM scheme, when transmitting UL data packets, a plurality of terminals simultaneously transmit signals to a base station having a plurality of receiving antennas through the same radio resource region, and the base station receives multiple input / output signals from each terminal. To detect the signal.

When the CSM scheme is applied, a plurality of terminals transmit a signal using the same radio resource, and thus, in the case of the CSM burst, another burst that does not use the CSM scheme (hereinafter, referred to as a non-CSM burst). The Carrier to Interference and Noise Ratio (CINR) is set higher than that of the " CINR. &Quot;

However, in the conventional wireless communication system, a method for informing a base station of power control information applying an appropriate required CINR to a terminal to transmit a CSM burst has not been proposed. Accordingly, there is a need for a scheduling scheme that enables a mobile terminal (MS) to satisfy a required CINR for a CSM burst even without specific power control information for the CSM burst.

Accordingly, an object of the present invention is to provide an UL scheduling apparatus and method for improving the transmission rate of UL data packets in accordance with information of an MS in a broadband wireless communication system.

Another object of the present invention is to provide an UL scheduling apparatus and method using UL data packet information, transmission power information, and UL CINR of an MS in a broadband wireless communication system.

In addition, another object of the present invention is to provide a scheduling apparatus and method for performing UL scheduling for multiple bursts allocated to an MS when transmitting and receiving data using the CSM scheme in a broadband wireless communication system.

An apparatus for scheduling multiple bursts in a broadband wireless communication system according to an aspect of the present invention for achieving the above objects, the at least one uplink data packet corresponding to the bandwidth request of the terminal in any one of the multiple bursts A packet scheduler for scheduling to be allocated; An operator for determining a transmission power offset corresponding to the burst type to which the scheduled uplink data packet is assigned; And a generator for generating MAP information including uplink burst allocation information for the terminal and information of the determined transmission power offset.

In addition, in a broadband wireless communication system according to another aspect of the present invention, a scheduling method of multiple bursts including a Collaborative Spatial Multiplexing (CSM) burst and a non-CSM burst includes a CSM burst and an uplink data packet corresponding to a bandwidth request of a terminal. scheduling a packet to be assigned to any of the non-CSM bursts; Determining an MCS level and a transmission power level corresponding to the packet-scheduled uplink data packet using the maximum bytes for each Modulation and Coding Scheme (MCS) level according to the type of multiple bursts calculated for the terminal; Determining a transmission power offset according to the burst type to which the packet-scheduled uplink data packet is allocated using the determined MCS level and transmission power level; And generating MAP information for the terminal including burst allocation information of the uplink data packet and information of the determined transmission power offset.

In addition, when a base station of a broadband wireless communication system according to another aspect of the present invention receives a bandwidth request from a terminal, the base station configures an uplink data packet corresponding to the bandwidth request, and sets a CSM for the configured uplink data packet. Assigns a burst according to any one of a Collaborative Spatial Multiplexing (Collaborative Spatial Multiplexing) scheme and a non-CSM scheme, determines a transmit power offset corresponding to the scheme of the burst to which the uplink data packet is allocated, and determines the determined transmit power offset. Uplink scheduling is performed by using the uplink scheduling.

The present invention, prior to the CSM burst by performing the UL scheduling of the MS using the UL data packet information, transmission power information and UL CINR of the MS when transmitting and receiving the data packet of the MS applying the CSM scheme in a broadband wireless communication system Even without the MS, the transmission rate of the UL data packet can be improved, and the efficiency of using limited resources can be improved.

In particular, the present invention uses the UL data packet information, transmission power information and UL CINR of the MS to dynamically control the UL resource allocation, MCS level and transmission power level for the burst for transmitting and receiving the data packet of the CSM scheme to limit the limited resources. The data transmission rate can be improved. In addition, the present invention can easily perform scheduling for multiple bursts assigned to the MS in the same time period.

1 is a view schematically showing the structure of a base station in a broadband wireless communication system according to an embodiment of the present invention.

FIG. 2 is a diagram schematically illustrating a structure of the scheduler of FIG. 1.

3 is a diagram schematically illustrating a structure of the calculator of FIG. 2.

4 is a flowchart illustrating a method of generating a resource table for UL scheduling according to an embodiment of the present invention.

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

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

1 is a view schematically showing the structure of a base station in a broadband wireless communication system according to an embodiment of the present invention.

In this case, in FIG. 1, a broadband wireless communication system according to an embodiment of the present invention is referred to as Orthogonal Frequency Division Multiplexing (OFDM) in an Institute of Electrical and Electronics Engineers (IEEE) 802.16 communication system. ) Is a broadband wireless communication system using an Orthogonal Frequency Division Multiple Access (OFDMA) scheme.

In addition, FIG. 1 shows that a base station (BS) according to an embodiment of the present invention allocates multiple bursts to an MS by applying collaborative spatial multiplexing (CSM). It was.

As shown in Figure 1, the BS according to the embodiment of the present invention, the interface 110 for processing the data when transmitting and receiving data with the upper end, the band signal processor 120 for modulating / demodulating and signing / decoding the data, modulation And a transmitter 130 for transmitting the encoded data to the MS, a receiver 160 for receiving data from the MS, a downlink (hereinafter referred to as DL), and scheduling for data transmission and reception in UL. A scheduler 150, and an antenna 140 for transmitting and receiving data with the MS on the air (air).

First, at UL, receiver 160 receives and converts one or more radio signals transmitted by MSs through antenna 140 into a baseband signal. For example, the receiver 160 removes and amplifies the noise from the radio signals for data reception by the BS, down-converts the amplified signal to a baseband signal, and digitizes the down-converted baseband signal.

The receiver 160 according to an embodiment of the present invention includes a carrier to interference and noise ratio (CINR) in UL measured for UL data packets received from the MS and neighbor cells measured for the MS in a multi-cell environment. Transmits a noise and interference (NI) to the scheduler 150. In addition, the receiver 160 receives a transmission power report message including total transmission power, current transmission power, and available transmission power information from the MS and transmits transmission power report information to the scheduler 150.

The band signal processor 120 extracts information or data bits from the digitized signal to perform demodulation, decoding, and error correction processes. The information or data bits that perform this process are transmitted to the adjacent wired / wireless network via the interface 110 or transmitted to other MSs provided with services from the BS through a transmission path.

In the DL, the interface 110 receives voice, data, or control information from a control station or a wireless network, and the band signal processor 120 encodes the received voice, data, or control information, and then transmits the transmitter 130. Will output The transmitter 300 modulates the encoded voice, data, or control information into a carrier signal having a transmission frequency or frequencies to be transmitted, amplifies the modulated carrier signal to a level suitable for transmission, and transmits the air through the antenna 140. Send by

The scheduler 150 controls the operations and respective components in the DL and UL.

In particular, the scheduler 150 according to an embodiment of the present invention uses the information of the MS and the channel information in the UL and the information of the multiple bursts received and received from the MS during UL scheduling. The byte is calculated and the maximum byte is used to determine the MCS level and the transmit power level for the data packet currently scheduled to the MS. The scheduler 150 determines the transmission power offset corresponding to the multiple burst type to which the currently scheduled data packet is to be allocated using the determined MCS level and the transmission power level.

In addition, the scheduler 150 generates MAP information including region information of multiple bursts to which at least one data packet scheduled is allocated, the determined MCS level and transmission power level information, and the determined transmission power offset information to the MS. Send.

For reference, a multi-burst is a burst for transmitting a data packet by applying a CSM method according to whether a CSM method is applied to data transmission and reception between a BS and an MS (hereinafter referred to as a 'CSM burst') and the CSM method. This does not apply and includes a burst for transmitting the data packet (hereinafter referred to as 'non-CSM burst'). In addition, multiple bursts are bursts that transmit data packets over a connection that does not support Hybrid Automatic Repeat Request (HARQ), which can be applied or not applied to CSM (hereinafter referred to as HARQ). The term " normal burst " and a burst for transmitting a data packet through a retransmission capable of supporting the HARQ (hereinafter referred to as a 'HARQ burst').

Hereinafter, a scheduling apparatus of a UL in a wireless communication system according to an embodiment of the present invention will be described in more detail with reference to FIG. 2.

FIG. 2 is a diagram schematically illustrating a structure of the scheduler of FIG. 1.

Referring to FIG. 2, the scheduler according to an embodiment of the present invention may include a packet scheduler 210 that performs packet scheduling for UL data packets of an MS, and an operator 220 that determines an MCS level and a transmission power level for the MS. And a generator 230 for generating MAP information including scheduling information about the MCS level and the transmission power level.

The packet scheduler 210 transmits a bandwidth request (BW-REQ: BW-REQ) message requesting UL resource allocation to transmit a UL data packet from the MS to the receiver 160. Received via BW-REQ message.

The packet scheduler 210 checks the information of the UL data packet to be transmitted by the MS through the BW-REQ message, and performs packet scheduling on the UL data packet of the MS. In this case, the information of the UL data packet is a connection that can distinguish the size (that is, the number of bytes) of the UL data packet and the type of burst to which the corresponding UL data packet is allocated, that is, a normal burst, a first and a second HARQ subburst. ) Types and types of services.

Specifically, the packet scheduler 210 stores information of at least one UL data packet for which bandwidth allocation is requested according to the order in which the bandwidth request of the MS is received, and includes a connection included in the information of each of the stored UL data packets. Connection) type and service type are checked, and packet scheduling is performed based on the priority of UL data packets. In this case, the packet scheduler 210 determines whether to pair the corresponding UL data packet, and performs packet scheduling so that the corresponding UL data packet is allocated to either burst of a CSM burst or a non-CSM burst.

In addition, the packet scheduler 210 transmits information of the packet scheduled UL data packet to the operator 220. In this case, the information of the UL data packet includes burst type information indicating that the corresponding UL data packet is allocated as a CSM burst or a non-CSM burst and size information (ie, number of bytes) of the UL data packet.

The operator 220 determines the transmission power offset of the currently scheduled UL data packet using parameters calculated through the information of the UL data packet (or burst) received from the MS, the transmission power report, and the like. In this case, the parameter includes a normalized CINR, normalized transmit power, transmit power density per MCS level, and maximum bytes for the received UL data packet.

Specifically, the operator 220 receives and confirms a CINR (hereinafter referred to as 'UL CINR') and a transmission power report in UL of the MS from the receiver 160. In this case, the calculator 220 checks the total transmission power, the current transmission power, and the available transmission power of the MS through the transmission power report.

The calculator 220 calculates normalized transmit power for the CSM burst and non-CSM burst received from the MS using the transmit power level of the MS and UL CINR, and uses the calculated normalized transmit power to calculate the CSM. Calculate capacity for bursts and non-CSM bursts.

Specifically, the operator 220 identifies a type of burst transmitted by the MS, that is, a CSM burst or a non-CSM burst, and a relative offset corresponding to the corresponding MCS level according to the type of burst transmitted by the MS. ). The relative offset may identify a HARQ relative offset or a CSM relative offset corresponding to each MCS level according to the burst type.

The calculator 220 calculates a normalized CINR using a relative offset according to the burst type, and calculates a normalized transmit power level using the normalized CINR. The operator 220 then uses the normalized transmit power level to calculate the capacity for the CSM burst or non-CSM burst. For reference, the calculator 220 calculates the transmission power density for each MCS level for the CSM burst or the non-CSM burst as the capacity, and the transmission power density for the MCS level and the total available transmission power of the MS (that is, The total remaining power) is used to calculate the total number of available subchannels and the maximum number of bytes for each MCS level according to multiple burst types.

For reference, the MCS level applicable to the UL data packet is QPSK (QPSK: Quadrature Phase Shift Key, hereinafter referred to as 'QPSK') 1/2 × 6 (QPSK1 / 2 repetition 6), QPSK1 / 2x4 (QPSK1 / 2 repetition 4), QPSK1 / 2x2 (QPSK1 / 2 repetition 2), QPSK1 / 2, QPSK3 / 4, 16QAM (QAM: Quadrature Amplitude Modulation, hereinafter referred to as 'QAM') / 2, 16QAM3 / 4 and so on.

The operator 220 generates MCS level and transmission power level information, total remaining power, and the calculated capacity information for the burst transmitted from the MS into a resource table.

Meanwhile, the operator 220 determines an appropriate MCS level and a transmit power level with reference to the resource table for the UL data packets scheduled by the packet scheduler 210, and transmit power offset corresponding to the determined MCS level. The power control information element including the information is transmitted to the generator 230.

The generator 230 generates MAP information including allocation information of the burst currently assigned to the MS, that is, size information and location information of a UL data packet to be transmitted by the MS. At this time, the generator 230 generates a MAP IE including the MCS level and the transmission power level information and the transmission power offset information determined for the multiple bursts assigned to the MS and transmits to the MS.

Hereinafter, a structure of an operator in a broadband wireless communication system according to an embodiment of the present invention will be described in more detail with reference to FIG. 3.

3 is a diagram schematically illustrating a structure of the calculator of FIG. 2.

As shown in FIG. 3, the calculator 220 according to an embodiment of the present invention includes an MCS level checking unit 302 for checking an MCS level of a multiple burst transmitted from an MS, and a CINR for calculating a normalized CINR for the multiple burst. Normalization unit 304, a transmission power normalization unit 306 for calculating a normalized transmission power level for the multiple bursts, and a capacity for determining the capacity (i.e., total number of subchannels available and maximum bytes) for the multiple bursts. A decision unit 308, a resource storage unit 310 for storing capacity information on the multiple bursts, a scheduling unit 312 for allocating multiple bursts for UL data packets to be scheduled, and the allocated multiple bursts An offset determination unit 314 for determining a transmission power offset.

The MCS level checking unit 302 checks the MCS level of the predetermined burst by obtaining information about a predetermined burst transmitted by the MS through UL.

The CINR normalization unit 304 calculates a normalized CINR by normalizing the UL CINR measured by the BS for the predetermined burst to a reference MCS level (in the embodiment of the present invention, set to QPSK1 / 2). In this case, the CINR normalization unit 304 further calculates a normalized CINR by using relative offsets of the HARQ burst and the CSM burst according to whether the HARQ scheme and the CSM scheme are applied to the predetermined burst.

For reference, the normalized CINR calculated by the CINR normalization unit 304 refers to a normalized CINR based on a required CINR corresponding to the reference MCS level, and the normalized CINR may be calculated through Equation 1 below. have.

[Equation 1]

In Equation 1, NCINR _{norm_㏈} [k] means the normalized CINR of the power scale for the kth burst received from the MS. In this case, NCINR _{norm_k} [k] is a normalized CINR of the non-CSM burst criterion. And, CINR _㏈ [k] means the measured CINR of the ㏈ scale for the k-th burst, HARQ_Offs means HARQ relative offset relative to the measured burst, the measured burst is not HARQ burst In case of burst, it has '0'. In addition, Off _{M_CSM_MCS} is a CSM relative offset with respect to the measured burst, and has a value of '0' when the measured burst is a non-CSM burst. C / N [k] means the required CINR for the MCS level applied to the kth burst, C / N _{QPSK1 / 2} means the required CINR for QPSK1 / 2, and R [k] means the kth burst. Denotes the number of repetitions of the MCS level with respect to R ₁ , and R ₁ has a value of 1 as the number of repetitions of the reference MCS level (ie, QPSK 1/2).

The transmission power determination unit 306 checks the transmission power level for the predetermined burst through the transmission power report message reported from the MS, and transmits the relative power offset according to the checked transmission power level and the type of the predetermined burst, and the The normalized CINR is used to determine the normalized transmit power level.

Here, the normalized transmission power level of the transmission power level reported from the MS may be calculated through Equations 2 and 3 below.

[Equation 2]

In Equation 2, NTP _TPR means an effective normalized transmit power level with respect to the transmit power reported from the MS. In this case, TRP in Equation 2 means a transmission power level reported from the MS, and is obtained from a header of the transmission power report message transmitted by the MS. C / N _{QPSK1 / 2} means a required CINR for QPSK1 / 2, and C / N _{MCS_TPR} indicates a required CINR for the MCS level of the burst that transmitted the transmission power report message header and the bandwidth request, that is, a normalized CINR. it means. In addition, R _{MCS_TPR} means the number of repetitions of the header of the transmission power report message and the MCS level of the burst that transmitted the bandwidth request, Off _{CSM-MCS_TPR} is the CSM relative power offset to the MCS level of the transmission power report message header For non-CSM bursts, it has a value of '0'.

[Equation 3]

In Equation 3, NTP means normalized transmit power. In this case, NTP _valid means effective normalized transmission power level, that is, NTP _TPR calculated through Equation 2, and Off _N-CSM means offset based on a filtered offset, that is, non-CSM burst.

The capacity determiner 308 calculates the transmit power density for each MCS level according to the type of multiple bursts using the normalized transmit power level determined by the transmit power determiner 306. In this case, the capacity determining unit 308 may calculate the transmission power density corresponding to the MCS level of the predetermined burst through Equation 4 below.

[Equation 4]

In Equation 4, P _MCS denotes a transmission power density corresponding to a specific MCS level. In this case, in Equation 4, C / N _MCS denotes a required CINR of the specific MCS level, R _MCS denotes the number of repetitions of the specific MCS level, and Off _CSM-of-MCS denotes a CSM for the specific MCS level. Relative power offset of the burst, '0' for non-CSM bursts.

The capacity determiner 308 calculates the total number of available subchannels using the transmission power density determined through Equation 4, and uses the calculated subchannels to maximize the MCS level according to the type of multiple bursts. Determine the byte. Here, the total number of available subchannels can be calculated by Equation 5 below, and the maximum byte can be determined by Equation 6 below.

[Equation 5]

In Equation 5, SCh _Total means the total number of available subchannels, and SCh _Zone is the total number of subchannels in the allocated area. For reference, when applying a 1024 fast Fourier transform (FFT), the total number of subchannels in the allocated area is 35. And, TP _rem means the total transmission power available for the MS, SCar _Subchannel means the number of subcarriers per subchannel.

In the following Equation 6, MB _MCS denotes a maximum byte for the specific MCS level, D _{slot_per_SC} denotes the number of data slots per subchannel in the allocated region, and B _{per_slot_MCS} denotes a slot for the specific MCS level. Per byte.

[Equation 6]

The capacity determining unit 308 transmits the maximum byte for each MCS level according to the type of multiple bursts calculated through Equations 5 and 6 to the resource storage unit 310 and stores the maximum byte in the resource table.

The resource storage unit 310 stores the maximum bytes for each MCS level determined by the capacity determination unit 308 and the number of slots for each maximum byte in the form of a resource table. That is, the scheduling unit 312 according to the embodiment of the present invention may determine the MCS level having the maximum byte appropriate for the allocated burst using the resource table.

The resource storage unit 310 separately stores burst allocation information for UL data packets currently scheduled through the scheduling unit 312 in a resource table.

The scheduling unit 312 selects the MCS level and the transmission power level for the UL data packet scheduled in the current frame using the maximum number of bytes and slots for each MCS level according to the type of multiple bursts determined by the capacity determining unit 310. . At this time, the scheduling unit 312 determines the appropriate MCS level and transmission power level by comparing the size information of the currently scheduled UL data packet with the maximum number of bytes per MCS level.

The scheduling unit 312 performs scheduling by allocating resources for UL data packets currently scheduled using the determined MCS level and the transmission power level. That is, the scheduling unit 312 allocates resources (ie, slots) to the UL data packet by using the number of bytes of the UL data packet currently scheduled and the number of bytes per slot corresponding to the determined MCS level.

In addition, the scheduling unit 312 updates the MCS level and transmission power level determined for the currently scheduled UL data packet and the allocated slot number in the resource table as burst allocation information, and generates the information of the scheduling performed. To send).

The offset determiner 314 determines the transmission power offset by checking the MCS level determined for the currently scheduled UL data packet determined by the scheduling unit 312. In this case, when the UL data packet to be currently scheduled is allocated to the CSM burst, the offset determiner 314 may determine a relative offset corresponding to the MCS level of the CSM burst in the previous frame for the corresponding MS stored in the resource storage 310. Transmit power offset for the data packet to be currently scheduled.

In detail, the offset determiner 314 may determine a transmission power offset for the UL data packet to be currently scheduled through Equation 7 below.

[Equation 7]

In Equation 7, Off _MCS is a transmission power offset at a corresponding MCS level for a burst to which the currently scheduled UL data packet is to be allocated, that is, a CSM burst and a non-CSM burst, and denotes a final offset for encoding a power control information element. it means. In Equation 7, Off _N-MCS refers to a filtered offset, that is, an offset corresponding to a corresponding MCS level based on a non-CSM burst, and PrevOff _{CSM_of_MCS} corresponds to a determined MCS level of a scheduled CSM burst in a previous frame. CSM means a relative offset. In Equation 7, Off _{CSM_of_MCS} is a CSM relative offset corresponding to the determined MCS level of the currently scheduled CSM burst and has a value of '0' when the burst is a non-CSM burst. As such, the offset corresponding to the current UL data packet determined through Equation 7 is stored in the resource storage unit 310 as the PrevOff _{CSM_of_MCS} after the scheduling of the current frame is completed.

The offset determiner 314 transmits the determined transmission power offset information to the generator 230.

Hereinafter, an operation of generating a resource table to be used by the base station BS for UL scheduling and a UL scheduling method in the broadband wireless communication system according to an embodiment of the present invention will be described with reference to FIGS. 4 and 5.

4 is a flowchart illustrating a method of generating a resource table for UL scheduling according to an embodiment of the present invention.

As shown in FIG. 4, in order to generate a resource table according to an embodiment of the present invention, a normalized CINR is first calculated using an MCS level applied to a UL burst transmitted from an MS and a UL CINR measured from the UL burst (S402). ). In this case, the normalized CINR is calculated using a relative offset value corresponding to the type of the UL burst (that is, the CSM burst and the non-CSM burst). For reference, the normalized CINR may be calculated through Equation 1.

Then, the normalized transmission power level for the UL burst is calculated using the calculated normalized CINR (S404). In this case, the normalized transmission power level is calculated using a transmission power level included in a transmission power report reported from the MS for the UL burst and a relative power offset value corresponding to the type of the UL burst. For reference, the normalized transmission power level may be calculated through Equations 2 and 3 above.

Next, the transmission power density for the UL burst is calculated at the applied MCS level using the calculated normalized transmission power level (S406). In this case, the transmission power density for each MCS level may be calculated by calculating the transmission power density corresponding to the applied MCS level using the calculated normalized transmission power level. In addition, when calculating the transmission power density for each MCS level, the MCS level and transmission power density for each burst type may be calculated using a relative power offset according to the type of burst. For reference, the transmission power density corresponding to the MCS level may be calculated through Equation 4.

Then, using the calculated transmission power density and the total remaining power included in the transmission power report of the MS, the total number of available subchannels corresponding to each burst type and MCS level for the MS is calculated (S408). . In this case, the total number of available subchannels may be calculated through Equation 5.

Then, the maximum byte corresponding to each burst type and MCS level is calculated using the total number of available subchannels (S410). In this case, the maximum byte for each burst type and MCS level may be calculated using the number of slots per subchannel in the allocated region and the number of bytes per slot corresponding to each MCS level. For reference, the maximum byte may be calculated through Equation 6.

Finally, the maximum byte corresponding to each calculated burst type and MCS level is stored as a resource table (S412). As such, the stored resource table may be referred to in determining an MCS level and a transmission power level for a UL data packet to be currently scheduled.

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

In FIG. 5, a burst allocation process is described after packet scheduling is performed according to a priority of a service and connection of UL data packets to be scheduled in a current UL frame according to the BW-REQ of the MS.

First, the information on the currently scheduled UL data packet is checked (S502). At this time, the type (ie, CSM burst or non-CSM burst) and size (ie, number of bytes) of bursts to which the UL data packet is allocated are identified.

The MCS level and the transmission power level to be applied to the data packet are determined using the information of the identified UL data packet (S504). In this case, the MCS level and the transmission power level are determined using a resource table in which a maximum byte corresponding to each burst type and MCS level is stored in advance. For reference, the maximum byte for each MCS level corresponding to the burst type corresponding to the burst type of the UL data packet is checked, and the size of the UL data packet is compared with the maximum byte for each MCS level and the size of the UL data packet. Determine the MCS level to apply.

Thereafter, the transmission power offset according to the burst type of the UL data packet is calculated using the determined MCS level and the transmission power level (S506). In this case, when the burst type of the UL data packet is a CSM burst, the transmission power offset is calculated using the CSM relative offset of the CSM burst allocated for the same MS of the previous frame and the CSM relative offset corresponding to the determined MCS level. . For reference, the offset may be calculated through Equation 7.

Finally, the calculated transmission power offset is updated to the CSM relative offset of the previous frame, and MAP information including the calculated transmission power offset and burst information to which the UL data packet is allocated is generated (S508).

Although the present invention has been described in detail with reference to preferred embodiments, it will be apparent to those skilled in the art that the present invention may be embodied in other specific various forms without changing the technical spirit or essential features of the present invention. One embodiment is to be understood in all respects as illustrative and not restrictive.

In addition, the scope of the present invention is specified by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts are included in the scope of the present invention. Should be interpreted as

Claims (14)

1. An apparatus for scheduling multiple bursts in a broadband wireless communication system,

   A packet scheduler for scheduling at least one uplink data packet corresponding to a bandwidth request of the terminal to be allocated in any one of the multiple bursts;

   An operator for determining a transmission power offset corresponding to the burst type to which the scheduled uplink data packet is assigned; And

   And a generator for generating MAP information including uplink burst allocation information and the determined transmission power offset information for the terminal.
2. The method of claim 1,

   The type of the multi-burst, characterized in that the Collaborative Spatial Multiplexing (CSM) burst and non-CSM burst.
3. The method of claim 1,

   The calculator,

   The MCS level to be applied to the scheduled uplink data packet is determined using the maximum bytes for each Modulation and Coding Scheme (MCS) level calculated corresponding to the type of multiple bursts for the terminal, and the scheduled uplink And a transmission power offset corresponding to the determined MCS level according to the type of multiple burst to which a data packet is allocated.
4. The method of claim 1,

   The calculator,

   A capacity determining unit that calculates a transmission power density and a maximum byte for each MCS (Modulation and Coding Scheme) level corresponding to a type of multiple bursts by using a normalized transmission power previously calculated corresponding to an uplink burst received from the terminal. ;

   A scheduling unit which determines an MCS level and a transmission power level corresponding to the scheduled uplink data packet by using the calculated maximum byte for each MCS level; And

   And an offset determiner configured to determine a transmission power offset corresponding to the determined MCS level according to the multi-burst type to which the scheduled uplink data packet is allocated.
5. The method of claim 4, wherein

   The calculator,

   Computing a normalized CINR using at least one parameter of an applied MCS level, a measured carrier to interference and noise ratio (CINR), and a CSM relative offset corresponding to the applied MCS level for an uplink burst received from the terminal. CINR normalization unit; And

   The received signal is received using at least one parameter of a current transmit power corresponding to the received uplink burst, the calculated normalized CINR, and a CSM relative power offset corresponding to the MCS level applied to the received uplink burst. And a transmission power normalization unit for calculating normalized transmission power for the uplink burst.
6. The method of claim 1,

   The calculator,

   When the scheduled uplink data packet is allocated with a Collaborative Spatial Multiplexing (CSM) burst, it corresponds to a CSM relative offset corresponding to a Modulation and Coding Scheme (MCS) level applied to a CSM burst assigned to a previous frame and the determined MCS level. And the transmission power offset is determined using the CSM relative offset.
7. The method of claim 1,

   The multi-burst to which the scheduled uplink data packet is allocated,

   A scheduling apparatus, characterized in that a normal burst or a hybrid automatic repeat reQuest (HARQ) burst of a Collaborative Spatial Multiplexing (CSM) scheme or a normal burst or HARQ burst of a non-CSM scheme.
8. A method of scheduling multiple bursts including Collaborative Spatial Multiplexing (CSM) bursts and non-CSM bursts in a broadband wireless communication system,

   Scheduling a packet such that an uplink data packet corresponding to a bandwidth request of the terminal is allocated to one of a CSM burst and a non-CSM burst;

   Determining an MCS level and a transmission power level corresponding to the packet-scheduled uplink data packet using the maximum bytes for each Modulation and Coding Scheme (MCS) level according to the type of multiple bursts calculated for the terminal;

   Determining a transmission power offset according to the burst type to which the packet-scheduled uplink data packet is allocated using the determined MCS level and transmission power level; And

   Generating MAP information for the terminal including burst allocation information of the uplink data packet and information of the determined transmission power offset.
9. The method of claim 8,

   Prior to determining the MCS level and transmit power level,

   Calculate maximum byte per MCS level according to CSM burst and non-CSM burst type by using uplink burst information received from the terminal, transmission power information, and measured uplink carrier to interference and noise ratio (CINR). The scheduling method further comprises the step of.
10. The method of claim 9,

    Computing the maximum byte for each MCS level,

    Calculating a normalized CINR for the uplink burst using the MCS level applied to the received uplink burst and the CINR measured for the received uplink burst;

    Calculating normalized transmit power using the calculated normalized CINR and a current transmit power corresponding to the received uplink burst; And

    Calculating transmission power density for each MCS level according to the type of multiple bursts using the calculated normalized transmission power, and calculating a maximum byte corresponding to the transmission power density.
11. The method of claim 9,

    In calculating the maximum byte for each MCS level,

    The normalized CINR and the normalized transmission power are calculated using the CSM relative offset corresponding to the type of the received uplink burst and the applied MCS level.
12. The method of claim 8,

    In determining the transmit power offset,

    When the uplink data packet is allocated with a CSM burst, determining the transmit power offset using the CSM relative offset corresponding to the MCS level applied to the CSM burst of the previous frame and the CSM relative offset corresponding to the determined MCS level. Scheduling method characterized by.
13. A base station of a broadband wireless communication system,

    When receiving a bandwidth request from the terminal, the uplink data packet corresponding to the bandwidth request is set, and according to any one of the Collaborative Spatial Multiplexing (CSM) method and the non-CSM method for the configured uplink data packet A base station for allocating a burst, determining a transmit power offset corresponding to a scheme of the burst to which the uplink data packet is assigned, and performing uplink scheduling using the determined transmit power offset.
14. The method of claim 13,

    The base station,

    When the uplink data packet is allocated in the burst of the CSM scheme, the CSM relative offset corresponding to the Modulation and Coding Scheme (MCS) level applied to the CSM burst of the previous frame and the MCS level determined corresponding to the uplink data packet The base station, characterized in that for determining the transmission power offset using the relative offset CSM.

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