KR20100088952A - Method and system for determining sounding reference signal transmitting bandwidth at mobile telecommunication - Google Patents

Abstract

PURPOSE: A SRS transmission bandwidth determination method and a system thereof are provided for a base station to efficiently determine SRS transmission bandwidth in consideration of an uplink channel environment of a terminal. CONSTITUTION: A user device(400) calculates transmission power about a SRS bandwidth having different length which is possible to transmit(S630). The user device extracts transmission power which does not exceed maximum transmission power from the calculated transmission power. The user device determines SRS candidate bandwidth(S640). A node B(500) receives the SRS candidate bandwidth transmitted from the user device. The base station determines the SRS transmission bandwidth(S670).

Description

Method and System for Determining SRS Transmission Bandwidth in Mobile Communication System {METHOD AND SYSTEM FOR DETERMINING SOUNDING REFERENCE SIGNAL TRANSMITTING BANDWIDTH AT MOBILE TELECOMMUNICATION}

The present invention relates to a method and system for determining the SRS transmission bandwidth in a mobile communication system. More specifically, the present invention relates to a method and system for determining an SRS transmission bandwidth in which a terminal calculates a transmittable SRS candidate bandwidth and transmits the SRS candidate bandwidth to a base station, and determines the SRS transmission bandwidth based on the SRS candidate bandwidth.

In a system in which a base station schedules resources for uplink (UL), the base station must determine uplink channel state for resource allocation. To this end, the base station receives the mutually-promised signal from the user equipment (UE) to determine the uplink state for each terminal.

In 3GPP Long Term Evolution (LTE), a base station receives a sounding reference signal (SRS) from a terminal to obtain uplink information. Then, the base station acquires channel state information on the uplink of the terminal using the SRS, and performs frequency selective scheduling, power control, timing estimation, and the like based on this.

Prior to transmitting the SRS to the base station, the conventional terminal receives the SRS configuration information from the base station and transmits the SRS to the base station based thereon. Here, the SRS configuration information includes transmission bandwidth information, sequence information, period information, frequency information, and the like used for SRS transmission.

However, since the base station cannot know the maximum transmittable power of the terminal, the base station arbitrarily sets the transmission bandwidth of the terminal included in the SRS configuration information. According to the prior art, the base station allocates the SRS transmission bandwidth of the terminal in a state in which the uplink state of the terminal is not accurately determined, and there is a problem in that the terminal cannot perform accurate SRS transmission.

Therefore, there is a need for the base station to accurately determine the uplink state of the terminal and reflect it in the SRS configuration information to more accurately determine the SRS transmission bandwidth of the terminal.

The present invention has been made to solve the above problems, and when setting the SRS transmission bandwidth of the terminal, the base station provides a method for efficiently determining the SRS transmission bandwidth in consideration of the uplink channel environment of the terminal. There is a purpose.

In addition, when the terminal calculates the SRS power according to the bandwidth, and transmits the transmittable SRS candidate bandwidth to the base station, the base station determines the SRS transmission bandwidth of the terminal based on the information received from the terminal.

In the SRS transmission bandwidth determination method of the present invention for solving the above problems, the terminal transmits a random access request message for establishing a call to the base station, the base station receives the random access request message in response to Transmitting a random access response message to the terminal, when the terminal receives the random access response message, calculates transmission power for each transmittable SRS bandwidth having a different length and includes an RRC connection request message including transmission power information; Transmitting an RRC connection response message including the determined SRS transmission bandwidth information to the terminal by the base station determining the SRS transmission bandwidth of the terminal by using the transmission power information and the terminal. SRS transmission determined by the Depending on the bandwidth characterized in that it comprises the step of transmitting the SRS to the base station.

In addition, the SRS transmission bandwidth determination system for solving the above problems calculates the transmission power for each transmittable SRS bandwidth having a different length and extract the transmission power does not exceed the maximum transmission power from the calculated transmission power A base station for determining an SRS candidate bandwidth, receiving a terminal for transmitting the determined SRS candidate bandwidth to a base station and receiving the SRS candidate bandwidth transmitted from the terminal to determine an SRS transmission bandwidth, and for transmitting the determined SRS transmission bandwidth to the terminal Characterized in that it comprises a.

According to the present invention, when a terminal calculates a transmittable SRS candidate bandwidth and transmits the same to the base station, the base station determines the SRS transmission bandwidth based on the transmittable SRS candidate bandwidth of the terminal. Therefore, the base station can more accurately determine the uplink state of the terminal to efficiently perform uplink resource allocation.

The Sounding Reference Signal (SRS) bandwidth of the present invention means a type of frequency length divided according to each level when a transmission band through which a terminal can transmit an SRS to a base station is divided into a tree structure. In other words, when the bandwidth of '40RB' is divided into a tree structure, the SRS bandwidth may be '40RB', '20RB,' 4RB ', or the like.

In addition, the SRS candidate bandwidth of the present invention means the largest power value that does not exceed the maximum transmission power of the terminal among the transmission powers calculated for each SRS bandwidth.

In addition, the SRS transmission bandwidth of the present invention means the SRS bandwidth determined for the terminal to transmit the actual SRS to the base station.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of well-known functions and constructions that may obscure the gist of the present invention will be omitted.

1 is a flowchart illustrating a message flow and an SRS transmission time point during an RRC connection between a terminal 110 and a base station 120 according to the prior art.

In the 3GPP LTE system, the terminal 110 transmits the SRS to the base station in the RRC connected mode. Then, the base station 120 receives the SRS and schedules an uplink resource.The configuration information necessary for the terminal 110 to transmit the SRS includes a base station through an RRC connection setup message when an RRC connection is made. The terminal 110 transmits the SRS to the base station 120 according to the allocated resource information.The SRS configuration information includes sequence information, period information, and frequency information used for the SRS. The initial power of the SRS is determined according to the information on the power control, which will be described in more detail with reference to the flowchart shown in FIG.

First, the terminal 110 transmits a random access request message to the base station 120 in order to establish a call in step S110. Then, the base station 120 receives the random access response message to the terminal 110 in step S120 to the terminal 110, the timing (timing) difference between the terminal 110 and the base station 120, and the RRC connection request Resource allocation information for transmitting a message is informed.

Upon receiving the random access response message from the base station 120, the terminal 110 transmits an RRC access request message to the base station 120 through the allocated uplink resource in step S130. Here, the unique number information of the terminal 110 and the purpose of call connection are transmitted in the RRC access request message.

Upon receiving the RRC connection request message from the terminal 110, the base station 120 transmits an RRC connection establishment message for establishing an RRC connection to the terminal 110 in step S140. The RRC connection setup message includes SRS configuration information and power control information of the terminal. Here, the SRS configuration information includes SRS bandwidth information, sequence information, period information, and frequency information used for the SRS. The power control information includes information on the SRS transmission power of the terminal.

After receiving the RRC connection configuration message, the terminal 110 transmits the SRS to the base station in step S150 according to the corresponding information. Then, when the base station 120 receives the SRS transmitted from the terminal 110, the base station 120 can grasp the state on the frequency of the terminal 110 and perform frequency selective scheduling.

Here, after the RRC connection, the terminal 110 determines the SRS transmission power using Equation 1 below.

[Equation 1]

[dBm]

[dBm]

Here, the description of the variables shown in Equation 1 is described in Table 1 below.

TABLE 1

variable meaning Pmax Maximum transmittable power value of the terminal α

중에 기지국이 결정하여 단말기에게 알려주는 값

That the base station determines and informs the terminal during PL Downlink path loss value measured by the terminal Ks When Ks = 1.25, Psrs_offset is a value between -3 ~ 12dB and 1dB interval when Ks = 1, and Psrs_offset is a value between -10.5 ~ 12dB and 1.5dB interval when Ks = 0. Msrs A value determined by the base station as the SRS transmission bandwidth in the subframe 'i' and informed to the terminal Po_pusch (j) Po_nominal_pusch (j) and Po_ue_pusch (j) are added and received from the base station, respectively. f (i) Value determined through power control in subframe 'i'

Meanwhile, the base station 120 allocates the SRS on the frequency based on the tree structure. The terminal 110 performs SRS hopping to transmit the SRS for the entire uplink data transmission bandwidth based on the tree structure. In other words, the terminal 110 repeatedly transmits the SRS while maintaining the same transmission bandwidth and changing only the transmission frequency. Here, an example of a tree structure (hereinafter, referred to as an 'SRS allocation tree structure') in which the base station 120 allocates an SRS of a terminal on a frequency is illustrated in FIG. 2.

2 is a diagram illustrating an example of an SRS allocation tree structure in which the base station 120 allocates an SRS of a terminal on a frequency. Herein, it is assumed that the SRS transmission region is 40 RB (Resource Block) in frequency. The SRS allocation tree structure shown in FIG. 2 is just an embodiment and may be configured in other forms than the example shown in FIG. 2.

Assume that the index for the level of the SRS allocation tree structure shown in FIG. 2 is 'b'. Then, the highest level (b = 0) of the SRS allocation tree structure consists of one SRS bandwidth of 40 RB bandwidth. At the second level (b = 1), two SRS bandwidths of 20 RB bandwidth are generated from the SRS bandwidth of 'b = 0' level. Accordingly, two SRS bandwidths may exist in the entire data transmission band. In the third level (b = 2), five 4RB SRS bandwidths are generated from one 20RB SRS bandwidth at the level immediately above (b = 1), so that 10 4RB SRS bandwidths are included in one level.

The configuration of the SRS allocation tree structure may have various levels, SRS bandwidths, and SRS bandwidths per level according to the setting of the base station 120. In other words, although FIG. 2 assumes that the level is 3 (that is, b = 0, 1, 2), the SRS bandwidth of the lower level may be further provided, and another SRS allocation tree structure may be provided. It is as described above.

Here, the number of SRS bandwidths at level 'b' generated from one higher level SRS bandwidth is Nb, and the indexes for the Nb SRS bandwidths are defined as nb = {0, ..., nb-1}. Then, in the example shown in FIG. 2, the first terminal UE # 1 is allocated to the first SRS bandwidth (n1 = 0) of the two SRS bandwidths having the 20RB bandwidth at the 'b = 1' level. The SRS bandwidths of the second terminal UE # 2 and the third terminal UE # 3 are respectively the first SRS bandwidth (n2 = 0) and the third SRS bandwidth (n2 =) of the lower bandwidth with respect to the second 20RB SRS bandwidth. 2) assigned to a location.

The base station 120 may allocate resources for SRS transmission by avoiding collisions between terminals based on the SRS allocation tree structure.

3 is a diagram illustrating that each terminal hops and transmits an SRS on a frequency according to an SRS bandwidth set for each TTI (Transmit Time Interval).

When the SRS bandwidth is smaller than the total data transmission bandwidth, each terminal frequency hopping for several TTIs so that the base station can determine the uplink channel state of the terminal over the entire bandwidth. This will be described in detail with reference to the drawings illustrated in FIG. 3.

First, it is assumed that each TTI is classified as 'nsrs'. Then, in the first period nsrs = 0, the first terminal UE # 1 is assigned to 'n1 = 0', the second terminal UE # 2 is assigned to 'n2 = 5', and the third terminal (UE # 3) is assigned to 'n2 = 7'.

Similarly, in the second period nsrs = 1, the first terminal UE # 1 is assigned to 'n1 = 1', the second terminal UE # 2 is assigned to 'n2 = 1', and the third terminal ( UE # 3) is assigned to 'n2 = 2'. The same applies to the third period (nsrs = 2) and the fourth period (nsrs = 3).

In this way, each terminal hops the frequency for transmitting the SRS to determine the uplink channel state of the terminal for the entire bandwidth to the base station.

4 is a block diagram illustrating an internal structure of a terminal 400 for calculating transmit power according to bandwidth and transmitting a transmittable SRS candidate bandwidth to a base station according to an embodiment of the present invention. The terminal 400 according to the embodiment of the present invention includes an RF communication unit 410, a data processing unit 420, a storage unit 430, and a control unit 440. In particular, the controller 440 may include a power calculator 440A and a candidate bandwidth determiner 440B.

First, the RF communication unit 410 may include an RF transmitter for up-converting the signal-processed data into a transmission band frequency, and an RF receiver for down-converting and outputting a frequency of the received data into a base band band.

The data processor 420 may include a transmission data processor and a reception data processor (not shown in the drawing). The transmission data processor may include a coder for encoding a signal to be transmitted, a modulator for modulating the encoded signal, and a digital-to-analog converter for converting the modulated signal into an analog signal. have. Here, the coder may include a data coder for processing packet data and the like, and an audio coder for processing audio signals such as voice.

The received data processor may include an analog-to-digital converter for converting an analog signal into a digital signal, a demodulator for demodulating a modulated signal, and a decoder for decoding the demodulated signal. The decoder may include a data decoder for processing packet data and the like, and an audio decoder for processing audio signals such as voice.

The storage unit 430 stores an overall program required for the operation of the terminal 400 according to the embodiment of the present invention.

The controller 440 controls the overall operation of the terminal 400. In particular, the controller 440 of the terminal 400 according to the present invention may calculate a power in each transmittable SRS bandwidth of the terminal, and control a series of processes of transmitting the same to the base station. To this end, the controller 440 may further include a power calculator 440A and a bandwidth determiner 440B.

The power calculator 440A calculates transmit power in all types of SRS bandwidths that can be transmitted by the terminal 400. Currently, since the maximum number of SRS bandwidths that can be transmitted according to the LTE standard is four, according to an embodiment of the present invention, the terminal 400 may calculate transmission power for each of the four types of SRS bandwidths. However, the type of the SRS bandwidth as described above is not necessarily limited to four.

The terminal 400 needs to calculate power in the SRS bandwidth before the RRC connection state. Therefore, the terminal 400 cannot calculate power in each SRS bandwidth by using Equation 1 that assumes an RRC connection state. Accordingly, the terminal 400 calculates power in each SRS bandwidth using Equation 2 below.

[Equation 2]

[dBm]

[dBm]

Here, the description of the variables shown in Equation 2 is described in Table 2 below.

TABLE 2

variable meaning Pmax Maximum transmittable power value of the terminal Msrs A value determined by the base station as the SRS transmission bandwidth in the subframe 'i' and informed to the terminal nb Index for Possible SRS Bandwidth Po_nominal_pusch (j) Offset value measured at the terminal α

중에 기지국이 결정하여 단말기에게 알려주는 값

That the base station determines and informs the terminal during PL Downlink path loss value measured by the terminal

The candidate bandwidth determiner 440B generates transmit power information by using the power value Psrs calculated according to each SRS bandwidth by the power calculator 440A. In the present invention, the transmission power information may be an SRS candidate bandwidth providing a reference for determining the SRS transmission bandwidth of the terminal.

To this end, the candidate bandwidth determiner 440B extracts a power value that does not exceed the maximum transmittable power Pmax of the terminal 440 from the calculated power value. The candidate bandwidth determiner 440B determines the bandwidth having the largest power value among the extracted power values as the SRS candidate bandwidth to be transmitted to the base station, and includes it in the RRC access request message. In this case, the terminal 400 may indicate the information on the SRS candidate bandwidth using the index (b = 0, 1, 2,...) For the level of the SRS allocation tree structure.

5 is a diagram illustrating an internal structure of a base station 550 that receives an SRS candidate bandwidth transmitted from the terminal 400 and determines the SRS transmission bandwidth of the terminal 400 according to the embodiment of the present invention. . The base station 550 may include an RF communication unit 510, a data processing unit 520, a storage unit 530, and a control unit 540. In addition, according to an embodiment of the present invention, the controller 540 may further include a transmission bandwidth determiner 540A.

5, the description of the RF communication unit 510, the data processing unit 520, and the storage unit 530 of the base station 500 is described in the RF communication unit 410, the data processing unit 520, and the storage unit of the terminal. Since it corresponds to 430, a detailed description thereof will be omitted.

The controller 540 of the base station 500 controls the overall operation of the base station. In particular, the control unit 540 of the base station 500 according to the present invention may further include a transmission bandwidth determining unit 540A.

The transmission bandwidth determining unit 540A receives the SRS candidate bandwidth transmitted from the terminal 400, and determines the SRS transmission bandwidth of the terminal based on this. According to an embodiment of the present invention, the transmission bandwidth determining unit 540A determines a bandwidth equal to the SRS candidate bandwidth as an SRS transmission bandwidth, or a bandwidth smaller than the SRS candidate bandwidth as an SRS transmission bandwidth. You can decide. For example, when the SRS candidate bandwidth is '20RB', the transmission bandwidth determiner 540A may determine '20RB' or '4RB' as the SRS transmission bandwidth. The transmission bandwidth determining unit 540A determines the SRS transmission bandwidth by considering not only the SRS candidate bandwidth received from the terminal 400 but also an overall communication environment such as an uplink channel state and a load level.

In the related art, since the base station arbitrarily determined the SRS transmission bandwidth of the terminal without acknowledging the uplink channel state of the terminal, there was a problem that the terminal could not perform accurate SRS transmission. However, the base station 500 of the present invention may determine the SRS transmission bandwidth more accurately reflecting the uplink state by using the SRS candidate bandwidth information directly measured by the terminal 400.

6 is a flowchart illustrating a process of calculating an SRS candidate bandwidth that can be transmitted by the terminal 400 and determining the SRS transmission bandwidth of the terminal 400 by the base station 500 according to an embodiment of the present invention. .

First, the terminal 400 transmits a random access request message to the base station 500 in order to set up a call in step S610. Then, the base station 500 receives the random access response message to the terminal 400 in step S620 and transmits the timing difference between the terminal 400 and the base station 500 and the RRC access request message to the terminal 400. Informs resource allocation information.

Upon receiving the random access response message from the base station 500, the terminal 400 calculates transmission power for all types of SRS bandwidths that can be transmitted in step S630. Referring to FIG. 2, the terminal 400 may divide an SRS bandwidth (40RB (if b = 0)) and 20RB divided into different lengths according to all levels (b = 0, 1, 2, ...). (when b = 1), the transmission power is calculated for 4RB (when b = 2, ...).

In this case, since the terminal 400 is not yet in the RRC connection state, it does not calculate the transmission power by the power calculation equation according to the prior art, and calculates the transmission power by the power calculation equation according to Equation 2 described above. Since Equation 2 has been described above, a detailed description thereof will be omitted.

The terminal 400 extracts transmission powers that do not exceed the maximum transmission power Pmax of the terminal among the transmission powers calculated by Equation 2 above. In operation S640, the terminal 400 determines the SRS bandwidth having the largest transmission power among the extracted transmission powers as the SRS candidate bandwidth.

In step S650, the terminal 400 adds the information on the determined SRS candidate bandwidth to the RRC access request message. In this case, the terminal 400 may indicate the information on the SRS candidate bandwidth using the index (b = 0, 1, 2,...) For the level of the SRS allocation tree structure.

In step S660, the terminal 400 generating the RRC access request message including information on the SRS candidate bandwidth transmits it to the base station 500. Then, the base station 500 determines the SRS transmission bandwidth of the terminal 400 on the basis of the SRS candidate bandwidth received from the terminal 400 in step S670. In step S680, the base station 500 transmits the determined SRS transmission bandwidth to the terminal 400 by including the RRC connection response message.

Then, the terminal 400 transmits the SRS to the base station 500 according to the SRS transmission bandwidth received from the base station 500 in step S690.

According to the present invention, since the terminal reports the SRS candidate bandwidth to the base station, and the base station determines the actual SRS transmission bandwidth based on the base station, the terminal can transmit the SRS to the base station more efficiently.

The embodiments of the present invention disclosed in the present specification and drawings are merely illustrative of specific embodiments of the present invention and are not intended to limit the scope of the present invention in order to facilitate understanding of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention can be carried out in addition to the embodiments disclosed herein.

1 is a flowchart illustrating a message flow and an SRS transmission time point during an RRC connection between a terminal 110 and a base station 120 according to the prior art.

2 is a diagram illustrating an example of an SRS allocation tree structure in which the base station 120 allocates an SRS of a terminal on a frequency.

3 is a diagram illustrating that each terminal hops and transmits an SRS on a frequency according to an SRS bandwidth set for each TTI (Transmit Time Interval).

4 is a block diagram illustrating an internal structure of a terminal 400 for calculating transmit power according to bandwidth and transmitting a transmittable SRS candidate bandwidth to a base station according to an embodiment of the present invention.

5 is a diagram illustrating an internal structure of a base station 550 for receiving an SRS candidate bandwidth transmitted from a terminal 400 and determining an SRS transmission bandwidth of the terminal 400 according to the embodiment of the present invention.

6 is a flowchart illustrating a process of calculating an SRS candidate bandwidth that can be transmitted by a terminal 400 and determining an SRS transmission bandwidth of the terminal 400 by the base station 500 according to an embodiment of the present invention.

Claims (8)

In the method of determining the SRS transmission bandwidth of the terminal in a mobile communication system, Sending, by the terminal, a random access request message for establishing a call to the base station; Receiving, by the base station, the random access request message and transmitting a random access response message to the terminal in response; When the terminal receives the random access response message, calculating transmission power for each transmittable SRS bandwidth having a different length, and transmitting an RRC connection request message including transmission power information to the base station; Determining, by the base station, the SRS transmission bandwidth of the terminal by using the transmission power information, and transmitting an RRC connection response message including the determined SRS transmission bandwidth information to the terminal; And And transmitting, by the terminal, the SRS to the base station according to the determined SRS transmission bandwidth. The method of claim 1, The terminal calculates the transmission power according to Equation 3 below. &Quot; (3) "

[dBm] Here, Pmax is the maximum transmittable power value of the terminal, Msrs is the SRS transmission bandwidth in the sub-frame 'i' is determined by the base station to inform the terminal, nb is the index for the possible SRS bandwidth, α is determined by the base station The value informing the terminal, PL, is a downlink path loss value measured at the terminal. The method of claim 2, wherein the transmitting of the RRC connection request message comprises: Determining, by the terminal, an SRS candidate bandwidth by extracting transmit power not exceeding the maximum transmit power of the terminal from the calculated transmit power; Generating an RRC connection request message including the determined SRS candidate bandwidth; And transmitting the generated RRC connection request message to the base station. The method of claim 3, wherein determining the SRS candidate bandwidth comprises: And determining an SRS bandwidth for the transmission power having the largest value among the extracted transmission powers as the SRS candidate bandwidth. In the SRS transmission bandwidth determination system of the terminal in a mobile communication system, The transmission power is calculated for each of the transmittable SRS bandwidths having different lengths, the transmission power not exceeding the maximum transmission power is extracted from the calculated transmission power to determine the SRS candidate bandwidth, and the determined SRS candidate bandwidth is determined by the base station. Terminal for transmitting to; And And a base station configured to receive the SRS candidate bandwidth transmitted from the terminal to determine an SRS transmission bandwidth and to transmit the determined SRS transmission bandwidth to the terminal. The method of claim 5, The terminal calculates the transmission power according to Equation 4 below. &Quot; (4) "

[dBm] Here, Pmax is the maximum transmittable power value of the terminal, Msrs is the SRS transmission bandwidth in the sub-frame 'i' is determined by the base station to inform the terminal, nb is the index for the possible SRS bandwidth, α is determined by the base station The value informing the terminal, PL, is a downlink path loss value measured at the terminal. The method of claim 5, The terminal determines the SRS bandwidth for the transmission power having the largest value of the extracted transmission power as the SRS candidate bandwidth, SRS transmission bandwidth determination system. The method of claim 5, And the terminal transmits an SRS to the base station according to the SRS transmission bandwidth determined by the base station.

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