KR20100048572A - Apparatus and method for minimizing interference of uplink channels in mobile telecommunication system and sounding reference signal receiver for the same - Google Patents

Abstract

PURPOSE: An apparatus and a method for minimizing interference of uplink channels in a mobile telecommunication system and a sounding reference signal receiver for the same are provided to improve SRS performance by minimizing the interference of PRACH influencing the SRS. CONSTITUTION: A CAZAC code corrector(63) extracts an SRS subcarrier and compensates a CAZAC code receiving a reference signal from a CAZAC(Constant Amplitude Zero Auto Correlation) code compensation transmitter. An interference information input unit(69) collects interference data, and an SRS puncturing controller(68) uses the interference data to calculates the interference of a PRACH(Physical Random Access Channel) overlapped with the SRS and determines a subcarrier having PRACH interference among the subcarrier of the SRS based on a CINR.

Description

A method for minimizing interference of an uplink channel in a mobile communication system and a SRS receiver for the same {APPARATUS AND METHOD FOR MINIMIZING INTERFERENCE OF UPLINK CHANNELS IN MOBILE TELECOMMUNICATION SYSTEM AND SOUNDING REFERENCE SIGNAL RECEIVER FOR THE SAME}

The present invention relates to a mobile communication system, and more particularly, to a PRACH (Sounding Reference Signal) in an uplink channel of a single carrier frequency division multiple access (SC-FDMA) -based Long Term Evolution (LTE) mobile communication system; The present invention relates to a method for improving SRS performance by minimizing interference of a physical random access channel, and an SRS receiver therefor.

The LTE system based on the Orthogonal Frequency Division Multiplexing (OFDM) scheme is currently being discussed in the 3rd Generation Partnership Project (3GPP) as a next generation mobile communication system to replace the Universal Mobile Telecommunication System (UMTS), which is the third generation mobile communication standard. The OFDM method transmits data using multiple subcarriers in the frequency domain, and maintains orthogonality among the subcarriers, thereby increasing frequency efficiency, selecting frequency fading, and selecting multiple fadings. It is strong in path fading and can reduce interference between symbols by using a protection period (CP). In addition, since the structure of the equalizer is simple in hardware, it has a strong advantage against impulse noise, and thus an optimum transmission efficiency can be obtained in high-speed data transmission.

3GPP LTE uplink performs a Discrete Fourier Transform (DFT) before subcarrier mapping to solve a Peak to Average Power Ratio (PAPR) problem of OFDM technology. This technique is called SC-FDMA in LTE. In LTE uplink, Zadoff-Chu CAZAC (hereinafter referred to as 'Constant Amplitude Zero Auto') having good auto-correlation and cross-correlation characteristics for initial synchronization setup using PRACH and synchronization using SRS is maintained. Correlation Code). CAZAC is a code used to generate a reference signal (RS).

In the uplink channel, a physical uplink control channel (PUCCH), a physical uplink shared channel (PUSCH), a physical random access channel (PRACH), and a sounding reference signal (SRS) channel are used. The PRACH is an LTE uplink channel transmitted by the terminal for initial synchronization. The PUCCH is an LTE uplink control channel and includes CQI information and ACK / NACK. PUSCH is an LTE uplink data channel. The SRS is one of RS (Reference Signals) of the LTE uplink by periodically transmitting the terminal, thereby maintaining the synchronization of the terminal to the initial synchronization of the uplink using the PRACH. In addition, it informs the channel quality of the uplink is used as input information of the base station uplink scheduler.

As described above, in the LTE uplink, the initial synchronization is set using the PRACH, and the terminal that has synchronized the initial synchronization through the PRACH periodically transmits the SRS to measure timing information to maintain the uplink synchronization. However, since the SRS uses the last SC-FDMA symbol of the subframe and the PRACH is intermittently located in the time domain, when the PRACH and the SRS meet in time in one subframe, there is a problem of causing interference with each other. Therefore, if the PRACH is expected to cause a significant amount of interference to the SRS, it is necessary to place the SRS exclusively with the PRACH in the frequency domain in order to minimize the interference of the PRACH. If the SRS and the PRACH are not exclusive in the time / frequency domain, interference of the PRACH to the SRS is inevitable and performance degradation of the SRS is inevitable. If the PRACH causes a significant amount of interference to the SRS, there is a need for a method capable of improving the performance of the SRS by minimizing the interference of the PRACH.

An object of the present invention is to provide an apparatus and method for improving the SRS performance by minimizing the interference of the PRACH on the SRS in the uplink channel of the LTE mobile communication system and an SRS receiver therefor.

According to an aspect of the present invention, a method for minimizing interference of an uplink channel in a mobile communication system is disclosed. According to an embodiment of the present invention, after allocating PUCCH and PRACH in the uplink frequency domain, subcarriers of the SRS are arranged exclusively with respect to the subcarriers of the PUCCH and PRACH, and the SRS is either higher frequency or lower frequency than PRACH. And subcarrier spacing with other channels is 0 or more. According to another embodiment of the present invention, upon receiving the reference signal from the SRS transmitter, the PRACH signal is detected through the PRACH receiver, and the timing and PRACH reception power are measured for each detected preamble. Based on the measured timing information and 'PRACH noise to signal power ratio (CINR) information based on PRACH reception power', the interference amount of PRACH overlapping the SRS is estimated, and the estimated interference amount and the received power or CINR of the user's SRS are estimated. Based on the subcarriers of the SRS, the subcarriers with interference of the PRACH are determined. After the SRS subcarrier extraction, before the zero padding of the CAZAC code compensated signal is performed, the determined subcarrier is removed. According to another embodiment of the present invention, when receiving a reference signal from the SRS transmitter, after extracting the SRS subcarrier, using the CAZAC code compensated information is searched for the SRS reception signal of the desired user, the received power or CINR of the SRS After checking, the reception power of each subcarrier to which the PRACH is allocated is calculated, and the calculated reception power and the average reception power of the SRS are compared to determine the subcarriers with interference of the PRACH among the subcarriers of the SRS. In the process before zero-padding the CAZAC code compensated signal, the determined subcarrier is removed.

According to another feature of the present invention, an SRS receiver for minimizing interference of an uplink channel in a mobile communication system is disclosed. The SRS receiver of the present invention includes a sounding reference signal (SRS) receiver of a mobile communication system, comprising: a CAZAC code compensator for receiving a reference signal from an SRS transmitter and compensating a CAZAC code after extracting an SRS subcarrier; An interference information input unit for collecting interference data capable of measuring an interference amount of the PRACH overlapping the SRS; Based on the interference data, the interference amount of PRACH overlapping the SRS is calculated, and based on the calculated interference amount and the 'received power or CINR of the user's SRS provided from the CAZAC code compensation unit, the subcarriers with PRACH interference among the subcarriers of the SRS SRS puncturing control unit for determining the; An SRS puncturing unit for removing subcarriers based on subcarrier removal information received from the SRS puncturing control unit; And SRS signal detection and channel estimation for detecting a signal by fast Fourier inverse transform (IFFT) after zero padding and estimating a channel in consideration of the degree of cancellation.

According to the present invention, there is an advantage in that the performance of the SRS can be improved by minimizing the interference of the PRACH on the SRS in the uplink channel of the LTE mobile communication system.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions will not be described in detail if they obscure the subject matter of the present invention.

1 and 2 are diagrams illustrating a mapping relationship between a structure of a PRACH and an SRS transmitter and subcarriers.

The CAZAC code used for PRACH and SRS in LTE uplink is defined as in Equation 1 (generating CAZAC code for PRACH) and Equation 2 (generating CAZAC code for SRS).

는 PRACH에 할당된 CAZAC 코드이고

는 SRS에 할당된 CAZAC 코드이며

와

는 소수이고, u와 q는 각각

와

보다 작은 양의 정수이다.here,

Is the CAZAC code assigned to the PRACH

Is the CAZAC code assigned to the SRS

Wow

Are prime numbers, u and q are each

Wow

Is a smaller positive integer.

In the LTE PRACH transmitter of FIG. 1, the CAZAC code for PRACH generated by the CAZAC code generator 11 (see Equation 1) is performed by the DFT performer 12, the PRACH subcarrier mapping unit 13, and an inverse DFT (IDFT:). Discrete Fourier Transform (DFT), Subcarrier Mapping, Discrete Fourier Transform (IDFT) through Inverse DFT) Execution Unit 14 and CP Adder 15 to insert guard intervals to help improve the performance of PRACH receiver in time domain. After the CP is added, it is transmitted to the base station.

(PRACH에 할당된 RB의 개수)개의 연속적인 RB(Resource Block)에 할당한다. (OFDM에서 주파수 영역은 부반송파로 이루어져 있는데, 상향링크에서는 12개의 연속적인 부반송파가 하나의 RB를 이룬다. RB는 스케쥴링 및 채널 할당의 기본 단위 가 된다.) 단, 하나의 RB는

(한 RB에 포함되어 있는 부반송파의 개수로서, 예컨대 12)개의 부반송파로 이루어지며, PRACH의 부반송파의 간격(Spacing)은 SRS의 부반송파 간격보다 작은데 이것의 비율을 K라고 하면

개의 RB에 PRACH는 최대

길이를 갖는 코드열을 넣을 수 있다. 일 예로 PRACH의 부반송파 간격이 1.25kHz이고 SRS가 15kHz이면 K는 12가 되고, PRACH가 사용하는 RB가 6,

가 12라면 PRACH의 최대 길이는 864(=6*12*12)가 된다. 여기서, PRACH의 코드 길이는 소수이어야 하고, 인접 채널간의 이격을 두기 위하여

는 839로 정할 수 있다.The position in the frequency domain of the _PRACH is offset k _PRACH ( k _PRACH represents the start position of the _PRACH in the frequency domain, and is expressed in units of the subcarrier size of the SRS).

(Number of RBs allocated to PRACH) is allocated to consecutive RBs (Resource Blocks). (In OFDM, the frequency domain consists of subcarriers. In uplink, 12 consecutive subcarriers form one RB. RB becomes the basic unit of scheduling and channel allocation.)

(As the number of subcarriers contained in the RB, for example, 12) made of a single sub-carrier, the distance (Spacing) of the PRACH sub-carrier is a sub-carrier interval jakeunde than this percentage of the SRS Speaking K

PRACH up to RB

You can put a string of lengths. For example, if the subcarrier spacing of the PRACH is 1.25 kHz and the SRS is 15 kHz, K becomes 12, and the RB used by the PRACH is 6,

Is 12, the maximum length of the PRACH is 864 (= 6 * 12 * 12). In this case, the code length of the PRACH should be a decimal number, and in order to space between adjacent channels,

Can be set to 839.

The SRS transmitter of FIG. 2 uses the SAZ CAZAC code (see Equation 2) generated by the CAZAC code generator 21 based on Equation 3 (SRS CAZAC code extension) below in the CAZAC code extension 22. To expand.

는 SRS가 사용하는 부반송파의 개수(즉, SRS에 사용되는 확장된 CAZAC 코드의 길이)이고,

는

를 넘지 않는 최대의 소수로 결정한다. SRS의 주파수 영역에서의 위치는 오프셋 k _SRS (k _SRS 는 주파수 영역에서 SRS의 시작위치를 나타내며, 부반송파의 크기를 단위로 한다. SRS 부반송파의 크기는 15kHz이 다) 다음에

개의 연속적인 RB안에서 부반송파의 단위에서 하나씩 엇갈려 배치시킨다. 그러므로,

와

에는 하기 수학식 4(SRS에 사용되는 확장된 CAZAC 코드의 길이)의 관계가 성립한다.here,

Is the number of subcarriers used by the SRS (ie, the length of the extended CAZAC code used for the SRS),

Is

Determines the largest prime number that does not exceed. The position of the SRS in the frequency domain is offset k _SRS ( k _SRS represents the starting position of the _SRS in the frequency domain, and is expressed in subcarriers. The size of the SRS subcarriers is 15 kHz.)

Staggered one by one in subcarrier units in consecutive RBs. therefore,

Wow

The relationship between Equation 4 (the length of the extended CAZAC code used for SRS) is established.

The SRS transmitter adds an SRS subcarrier mapping unit 23, an Inverse Fast Fourier Transform (IFFT) execution unit 24, and a CP to the SAZ CAZAC extension code (see Equation 3) extended by the CAZAC code extension unit 22. Subcarrier mapping, fast Fourier inverse transform (IFFT), and a CP for guard interval insertion are added to the base station to eliminate interference between symbols in the time domain.

On the other hand, the receiver structure of the PRACH and SRS is shown in FIG. Since the PRACH and the SRS are based on the CAZAC code, the receiver can be configured with a similar structure. As a difference, the PRACH receiver performs a discrete Fourier transform (DFT) and a discrete Fourier transform (IDFT) on the received signal (DFT performer 31, IDFT performer 35), and the SRS receiver performs a fast Fourier transform (FFT). And performing fast Fourier inverse transform (IFFT) (FFT performer 31, IFFT performer 35). The subcarrier demapping unit 32 performs subcarrier demapping to extract a signal of a subcarrier mapping region. As shown in Equation 5 below (CAZAC code compensation), the CAZAC code compensation unit 33 compensates the CAZAC code by taking a complex conjugate of the CAZAC code by multiplying the subcarrier demapped signal. The zero padding unit 34 performs a predetermined amount of zero padding on the CAZAC code compensated signal, and performs an IDFT or IFFT on the IDFT or IFFT execution unit 35 to perform a signal on the signal detector / channel estimator 36. Calculate detection, timing estimates, and received power.

Here, d (n) is a subcarrier de-mapped signal, e (n) is fft (x _PRACH ) for _PRACH , and r _SRS for _SRS .

However, the SRS uses the last SC-FDMA symbol of the subframe and the PRACH is located long in the time domain. How long the PRACH occupies in the time domain depends on the preamble format. The PRACH of FIG. 4 shows a result of using Preamble Format 0. FIG.

The PRACH is transmitted by the terminal to match the initial synchronization of the uplink. In this case, there is a Round Trip Delay (RTD). (RTD means propagation delay from the base station to the terminal and propagation delay from the terminal to the base station.) The terminal that is not uplink synchronized corrects the transmission timing by using the PRACH so that all terminals of the terminal are received from the base station. The reception time is kept constant. After the PRACH, synchronization is maintained periodically by using the SRS.) Although FIG. 4 illustrates the case where the RTD is 0 (the distance between the base station and the UE is 0), the RTD is generally 0 Value and the maximum RTD is determined by the size of the cell. As the RTD increases, the temporal position of the PRACH moves in the right direction. The UE, which has initially synchronized through the PRACH, periodically transmits the SRS to measure timing information to maintain uplink synchronization.

According to LTE TS36.211 v830, there are five PRACHs as shown in Table 1 below (random access preamble parameter). In the case of Preamble Format 0, as shown in FIG. 4, there is a temporal free space at the rear of the subframe, but as the RTD increases, the PRACH moves to the right, and the SRS meets the RTD after about 26 μs. In addition, when the length of the CP is increased or the sequence length is changed, it is inevitable that the SRS and the PRACH meet in time.

As such, when PRACH and SRS meet in time in one subframe, they may cause interference with each other. The solutions are summarized in two ways. One is to avoid collisions using other subcarriers in the frequency domain (collision avoidance method), and the other is to detect collisions and mitigate performance degradation when collisions are inevitable in the time / frequency domain (collision mitigation). Method).

As a collision avoidance method, a method of arranging PRACHs and SRSs in different areas in time (first collision avoidance method) and a method of not interfering with PRACHs and SRSs in a frequency domain if there is a case where PRACHs and SRSs meet in time There may be a second collision avoidance method.

Referring to the first collision avoidance scheme, for example, a PRACH (or SRS) is allocated to an odd subframe, and an SRS (or PRACH) is allocated to an even subframe so that PRACH and SRS are allocated to different regions in the same cell in time. To place. However, interference from other cells is inevitable.

Referring to the second collision avoidance scheme, after allocating the PRACH and the uplink control channel (PUCCH) in the frequency domain, the SRS avoids allocating subcarriers of the uplink control channel (PUCCH) and the PRACH.

Meanwhile, referring to the collision mitigation method, when the separation of the PRACH and the SRS is impossible in the time / frequency domain, the uplink receiver detects that the PRACH and the SRS collide with each other and responds appropriately. Information of the PRACH receiver can be used here.

According to the 3GPP specification (3GPP TS36.211 v830), the first collision avoidance scheme can be supported, but the second collision avoidance scheme cannot be supported. In addition, since the collision mitigation method depends on the implementation method of the receiver, it is not covered by 3GPP. If it is completely separated in the time / frequency domain, collision mitigation is not necessary. Otherwise, collision mitigation should be used to minimize interference to each other.

Preamlble Format CP length PRACH sequence length 0 3168 × T _s 24576 × T _s One 21024 × T _s 24576 × T _s 2 6240 × T _s 2 × 24576 × T _s 3 21024 × T _s 2 × 24576 × T _s 4 448 × T _s 4096 × T _s

* T _s = 1 / (15000 * 2048) seconds

In the following embodiment, a collision avoidance method and a collision mitigation method of PRACH and SRS will be described in detail.

In the collision avoidance method, PRACH and SRS or PUCCH and SRS should not be allocated to the same region in the time / frequency domain. In this embodiment, only the frequency domain is considered. The positions of the PRACH and the SRS in the frequency domain may be determined in a portion other than the guard region. In this embodiment, after allocating the PUCCH and the PRACH, the position of the subcarriers of the SRS is determined to determine the uplink channel (PUCCH) in which the SRS is different. , PRACH) and exclusive subcarrier allocation. For example, if the SRS is located above the PRACH (high frequency) (5a), the position of the SRS is determined as shown in Equation 6 (determining the offset of the SRS above the PRACH) and Equation 7 (determining the length of the SRS above the PRACH), If the SRS is located below the PRACH (low frequency) (5b), the position of the SRS is determined as shown in Equation 8 (determining the offset of the SRS below the PRACH) and Equation 9 (determining the length of the SRS below the PRACH). 5 is a channel configuration diagram for avoiding collision in the frequency domain of the LTE uplink.

In FIG. 5, "GAP" means an interval between an SRS and a PRACH or PUCCH, and a basic unit is 15 kHz. GAP is 0 or more to minimize interference between channels. k _PRACH indicates the start position of the _PRACH in the frequency domain, and is based on the size of the subcarrier of the SRS. k _SRS represents the starting position of the _SRS in the frequency domain, the unit size of the subcarrier. The size of the SRS subcarrier is 15 kHz.

Since the collision avoidance method of PRACH and SRS does not meet in the frequency domain, it is theoretically orthogonal to each other so that there is no interference to each other, but because the FFT / DFT of PRACH and SRS are different in size, even if the subcarriers are different, There is interference in the subcarriers. Therefore, in this embodiment, in order to minimize interference caused by adjacent subcarriers, a guard subcarrier (GAP) is added between SRS and PRACH and SRS and PUCCH to minimize interference. However, the size of each subcarrier for the guard interval may be different.

와

는 각각 인접한 PRACH와 PUCCH(상향 제어 채널)의 간섭을 최소화하기 위한 보호구간(Guard)이며,

는 저주주파수 혹은 고주파수쪽 상향 제어 채널의 RB 개수,

는 상향링크(UL)에 설정된 최대 RB 개수이다.

는 PRACH에 할당된 RB의 개수,

는 SRS에 할당된 RB의 개수,

는 한 RB에 포함되어 있는 부반송파의 수(예컨대, 12)이다. here

Wow

Are guard intervals for minimizing interference of adjacent PRACH and PUCCH (uplink control channel), respectively.

Is the number of RBs in the low frequency or high frequency uplink control channel,

Is the maximum number of RBs set for uplink (UL).

Is the number of RBs allocated to the PRACH,

Is the number of RBs allocated to the SRS,

Is the number of subcarriers (eg, 12) included in one RB.

If the length of the SRS sequence is smaller than the maximum length that can be allocated to the SRS, the hopping may be performed in the frequency domain. Even when the SRS hopping in the frequency domain, the above Equations 6 to 9 must be satisfied.

On the other hand, the collision mitigation method detects the effect of interference when the PRACH and SRS overlap in the time / frequency domain occurs and responds to it. FIG. 6 is a diagram schematically illustrating a configuration of an SRS receiver to which a method for minimizing interference of an uplink channel is applied according to an embodiment of the present invention, and shows a structure of an SRS receiver for minimizing interference by a PRACH.

As shown in FIG. 6, the SRS receiver of the present invention further includes an interference information input unit 69, an SRS puncturing control unit 68, and an SRS puncturing unit 64 in the SRS receiver of FIG. 3. do. The FFT performer 61, the SRS subcarrier demapping unit 62, the CAZAC code compensator 63, the zero padding unit 65, the IFFT performer 66, and the SRS signal detector / channel estimator 67 are described above. It performs the same function as the SRS receiver of FIG. The SRS receiver of the present invention includes an SRS puncturing unit 64 between the CAZAC code compensation unit 63 and the zero padding unit 65, and the SRS puncturing control unit 68 received from the CAZAC code compensation unit 63. Based on the own information and the interference information collected through the interference information input unit 69, information on the SRS subcarriers (subcarrier removal information) applied by the PRACH interference is generated and transmitted to the SRS puncturing unit 64, thereby interfering with the PRACH. Eliminate the affected SRS subcarriers or the entire SRS including them. Alternatively, the entire received SRS signal may be removed. In particular, since the signals received by the SRS puncturing control unit 68 from the CAZAC code compensator 63 include signals of several SRS users, the SRS puncturing control unit 68 extracts and receives a desired user signal from the signals of multiple users. Estimate the power. Hereinafter, the functions of the additional components will be described.

The interference information input unit 69 determines the input of the interference information and collects data for measuring the interference amount of the PRACH. When using the information of the PRACH receiver 30 (see FIG. 3) as input information, the SRS receiver of the present invention has the configuration as shown in FIG. 7, and the information in the SRS receiver is not received by the SRS receiver of the present invention from the outside. When using as the input information has a configuration as shown in FIG. In the following, it is assumed that a collision occurs in the time / frequency domain. It is also assumed that the starting point is the same in the frequency domain of the PRACH and the SRS.

As shown in FIG. 7, when the interference information input unit 69 uses the information of the PRACH receiver 30, the SRS receiver of the present invention uses the timing, the received power, or the signal power ratio to the noise detected by the PRACH receiver 30. SRS (the part affected by interference by PRACH) or the whole SRS including the same using the received power or signal-to-noise ratio (CINR) of the SRS estimated by the CINR) information and the CAZAC code compensator 63 Remove it. Alternatively, the entire received SRS signal may be removed. That is, the PRACH receiver 30 detects a PRACH signal as shown in FIG. 3, measures timing information, received power, or CINR value for each detected preamble, and transmits the measured information to the SRS puncturing control unit 68. The SRS puncturing control unit 68 receives the timing detected from the PRACH receiver 30 and the received power or CINR value to determine the interference interval of the PRACH on the SRS based on the timing information, and the interference in the corresponding interval based on the CINR value. Determine if this is big or small. Since the CINR means the power ratio to the noise, even if the PRACH receiver 30 transmits only the received power without calculating the CINR, the SRS puncturing control unit 68 knows the noise so that the CINR can be easily estimated. Therefore, the SRS puncturing control unit 68 may determine the amount of interference signal and the subcarrier with interference, the method of measuring the interference amount of PRACH on the SRS is represented by the following equation 10 (calculate PRACH interference power on the SRS) Calculated based on

The received power or CINR value of the PRACH transmitted from the PRACH receiver 30 to the SRS puncturing control unit 68 is an average value of the power or CINR value of each subcarrier to which the PRACH is allocated, or an individual value of each subcarrier to which the PRACH is allocated. It can be a power or CINR value. When the average value of the PRACH band is input from the PRACH receiver 30, the portion where the SRS and the PRACH overlap in the frequency domain is controlled by one unit. In one embodiment, the SRS puncturing control unit 68 compares each interference amount of subcarriers to which a PRACH is assigned to a threshold to determine a subcarrier to puncture, or compares an average of interference amounts of subcarriers to which a PRACH is assigned to a threshold. Therefore, the portions of the SRS and PRACH overlapping in the frequency domain are controlled by one unit.

Here, CINR _i and timing _i are the received power and timing estimated for the i-th preamble, and f (~) is the CINR and timing to calculate the interference amount of PRACH for the subcarriers overlapping the SRS.

If it is determined that the interference of the PRACH on the SRS is greater than the threshold (power ratio of the SRS region to the PRACH) (for example, the power of the SRS estimated from the signal received from the CAZAC code compensator 63 is 0 dB and is received from the PRACH receiver 30). When the power of the PRACH is 10 to 20 dB), the SRS puncturing control unit 68 instructs the SRS puncturing unit 64 to remove a portion corresponding to the PRACH (part of the SRS subcarrier with interference of the PRACH). In detail, the SRS puncturing control unit 68 informs the SRS puncturing unit 64 and the SRS signal detection unit / channel estimator 67 to inform the subcarriers that are punctured (transmit subcarrier removal information). The SRS puncturing unit 64 removes some subcarriers of the SRS (that is, the subcarriers of the SRS having large PRACH interference) by using the subcarrier removal information received from the SRS puncturing control unit 68 (see FIG. 9A), and the SRS signal detection unit The / channel estimator 67 detects a signal from which the subcarrier has been removed and estimates a channel in consideration of the removed subcarrier (that is, the remaining subcarriers except the subcarrier of the SRS having a large PRACH interference) (timing estimation and reception power calculation). ). At this time, the subcarriers removed in the CINR calculation of the SRS subcarriers are not included.

Here, the SRS puncturing unit 64 may remove the entire SRS or remove the entire received SRS signal using the subcarrier removal information received from the SRS puncturing control unit 68.

On the other hand, as shown in Figure 8, when the interference information input unit 69 uses the information of the SRS receiver itself of the present invention without depending on the information outside the SRS receiver, the SRS puncturing control unit 68 is a CAZAC code compensation unit Using the CAZAC code compensated information by 63, the power of each subcarrier to which the PRACH is allocated is calculated, and it is determined whether it is larger or smaller than the average received power of the SRS. Since the subcarrier to which the PRACH is allocated increases in power due to the interference of the PRACH, when the interference is caused by the PRACH, it is larger than the average reception power of the SRS. If the power of the subcarrier with PRACH is greater than the average reception power of the SRS, and the interference is determined to be large, the SRS puncturing control unit 68 punctures the SRS puncturing unit 64 and the SRS signal detecting unit / channel estimating unit 67. (Puncturing) informs the subcarrier, and accordingly, the SRS puncturing unit 64 uses a subcarrier removal information received from the SRS puncturing control unit 68 to use some subcarriers of the SRS (that is, subcarriers of the SRS having a large interference of PRACH). 9B, the SRS signal detector / channel estimator 67 detects a signal from which the subcarrier has been removed and considers the removed subcarrier (that is, the remaining subcarriers other than the subcarrier of the SRS having a large PRACH interference). Estimate the channel (timing estimation and receive power calculation). At this time, the subcarriers removed in the CINR calculation of the SRS subcarriers are not included.

In one embodiment, the SRS puncturing control unit 68 determines each subcarrier to puncture by comparing each of the powers of subcarriers to which the PRACH after the CAZAC code compensation has been allocated with a threshold (average receiving power of the SRS), or the CAZAC code A power average of subcarriers to which the PRACH is allocated after compensation is compared with a threshold to control a portion where the SRS and the PRACH overlap in the frequency domain as one unit.

In the above embodiment, it is assumed that the entire subcarriers overlapping the PRACH are controlled, but individual control of each subcarrier is also possible.

The method of removing some regions of the SRS proposed as the collision mitigation method can predict the performance as shown in FIG. 10 in Missing Probability and the symbol timing offset estimation performance as shown in Table 2 below in False alarm probability.

)은 40을 사용하여 수신 안테나가 2개인 환경에서 AWGN으로 모의실험하였다.In the simulation for the effect of the present invention, the CINR of the SRS is changed from -20 to 0 dB, and the CINR of the PRACH is kept constant even if the CINR of the SRS is changed. In addition, u used for the CAZAC code of the PRACH is 419, q used for the SRS is 7 and the bandwidth of the SRS (

) Is simulated with AWGN using two receive antennas using 40.

FIG. 10 is a Missing Probability for SRS CINR. Missing probability refers to a case in which a receiver fails to detect an SRS signal when the SRS is transmitted. Missing Probability of SRS becomes poor in Missing Probability as the target receiving power of PRACH increases. In other words, it can be seen that performance is degraded due to interference of the PRACH. On the other hand, if the performance is obtained after removing a certain portion of the SRS using the SRS receiver of the present invention, it can be seen that the PRACH interference is much better than the case of severe interference. Table 2 below shows the average false alarm, which increases to about 85% at 20dB of PRACH, but can be lowered to less than 0.1% when a certain portion of the SRS is removed.

Average False Alarm Punctured SRS 0.083% PRACH Target: -10 dB 0.091% PRACH Target: 0dB 0.142% PRACH Target: 10dB 2.174% PRACH Target: 20dB 84.351%

While the invention has been described in connection with some embodiments herein, it should be understood that various changes and modifications can be made therein without departing from the spirit and scope of the invention as would be understood by those skilled in the art. something to do. It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

1 illustrates the structure and subcarrier mapping relationship of a PRACH transmitter.

2 is a diagram illustrating a structure and a subcarrier mapping relationship of an SRS transmitter.

3 shows the structure of a PRACH / SRS receiver.

4 is a diagram illustrating an arrangement relationship in time and frequency domain of LTE uplink.

5 is a diagram illustrating a channel arrangement relationship to avoid collision in the frequency domain of the LTE uplink.

6 is a diagram schematically illustrating a configuration of an SRS receiver to which a method for minimizing interference of an uplink channel is applied according to an embodiment of the present invention.

7 is a diagram illustrating in detail the configuration of an SRS receiver according to an embodiment of the present invention.

8 is a diagram illustrating in detail the configuration of an SRS receiver according to another embodiment of the present invention.

FIG. 9A is an explanatory diagram showing a method for minimizing interference of an uplink channel according to an embodiment of FIG. 7; FIG.

FIG. 9B is an explanatory diagram showing a method for minimizing interference of an uplink channel according to another embodiment of FIG. 8; FIG.

10 is a graph showing performance results in accordance with an embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

61: FFT execution unit 62: SRS subcarrier demapping unit

63,73: CAZAC code compensation unit 64: SRS puncturing unit

65,74: zero padding section 66: IFFT performing section

67: SRS signal detector / channel estimator 68: SRS puncturing controller

69: interference information input unit

Claims (16)

A method for minimizing interference of an uplink channel in a mobile communication system, After allocating an uplink control channel (PUCCH) and a random access channel (PRACH) in an uplink frequency domain, subcarriers of a sounding reference signal (SRS) are arranged exclusively with respect to the subcarriers of the PUCCH and PRACH, and the SRS A method for minimizing interference in an uplink channel, which is disposed in either a high frequency region or a low frequency region than a PRACH, and sets a subcarrier spacing with another channel to 0 or more. The method of claim 1, If the SRS is located at a higher frequency than the PRACH, the SRS is arranged based on the following equation (1) and (2), the method for minimizing the interference of the uplink channel. (Equation 1): Determination of the offset of the SRS

(Equation 2): Determination of the length of the SRS

Where GAP is the interval between SRS and PRACH, k _PRACH is the starting position of _PRACH in the frequency domain,

Is a guard interval to minimize interference of adjacent PRACH,

Is the number of RBs allocated to the PUCCH,

Is the maximum number of RBs set for uplink (UL),

Is the number of RBs allocated to the PRACH,

Is the number of RBs allocated to the SRS,

Is the number of subcarriers included in one RB) The method of claim 1, If the SRS is located at a lower frequency than the PRACH, the SRS is arranged based on the following equation (1) and (2), the method for minimizing the interference of the uplink channel. (Equation 1): Offset determination of the SRS under the PRACH

(Equation 2): Determination of the length of the SRS lower PRACH

Where GAP is the interval between the SRS and the PRACH, k _PRACH is the starting position of the _PRACH in the frequency domain, k _SRS is the starting position of the _SRS in the frequency domain,

Is a guard interval to minimize interference of adjacent PUCCH,

Is the number of RBs allocated to the PUCCH,

Is the number of RBs allocated to the SRS,

Is the number of subcarriers included in one RB) A method for minimizing interference of an uplink channel in a sounding reference signal (SRS) receiver of a mobile communication system, Receiving a reference signal from an SRS transmitter; Detecting a PRACH signal through a random access channel (PRACH) receiver, and measuring timing and PRACH received power for each detected preamble; Based on the measured timing information and 'PRACH noise to signal power ratio (CINR) information based on the PRACH reception power', the interference amount of the PRACH overlapping the SRS is estimated, and the estimated interference amount and the received power or CINR of the user's SRS are estimated. Determining a subcarrier with interference of the PRACH among the subcarriers of the SRS; And A method for minimizing interference of an uplink channel, comprising: removing the determined subcarriers in a process of zero padding a CAZAC code compensated signal after SRS subcarrier extraction. The method of claim 4, wherein The PRACH receiver calculates and transmits the PRACH CINR to the SRS receiver based on the PRACH reception power; And calculating the PRACH CINR based on the PRACH received power transmitted from the PRACH receiver in the SRS receiver itself. The method of claim 5, The PRACH reception power and the PRACH CINR are the average values of the power or CINR value of each subcarrier to which the PRACH is allocated, or the individual power or CINR value of each subcarrier to which the PRACH is allocated, to minimize interference of an uplink channel. Way. A method for minimizing interference of an uplink channel in a sounding reference signal (SRS) receiver of a mobile communication system, Receiving a reference signal from an SRS transmitter; After extracting the SRS subcarriers, the SAZ received signal of the desired user is searched using the CAZAC code-compensated information, and the received power of each subcarrier allocated to the PRACH is examined by checking the received power or signal-to-noise ratio (CINR) of the corresponding SRS. Calculating; Comparing the calculated received power with the average received power of the SRS to determine a subcarrier with interference of PRACH among subcarriers of the SRS; And And removing the determined subcarriers prior to zero padding of the CAZAC code compensated signal. The method of claim 7, wherein The reception power of each subcarrier to which the PRACH is allocated is an average value of the power of each subcarrier to which the PRACH is allocated, or one of the individual power values of each subcarrier to which the PRACH is allocated. . The method according to any one of claims 4 to 8, In removing the determined subcarriers, an uplink channel for removing only subcarriers to be removed, removing all overlapping portions of the SRS and PRACH in the frequency domain, or selecting and removing any one of methods for removing the entire received SRS signal, Method for minimizing interference. 10. The method of claim 9, And detecting the signal by fast Fourier inverse transform (IFFT) after zero padding and estimating the channel in consideration of the degree of cancellation. As a SRS (Sounding Reference Signal) receiver of a mobile communication system, A CAZAC code compensator for receiving a reference signal from an SRS transmitter and compensating for a CAZAC code after extracting an SRS subcarrier; An interference information input unit for collecting interference data capable of measuring an interference amount of a random access channel (PRACH) overlapping the SRS; The interference amount of the PRACH overlapping the SRS is calculated using the interference data, and based on the calculated interference amount and the 'received power or signal-to-noise ratio (CINR) of the desired user's SRS provided from the CAZAC code compensation unit, An SRS puncturing control unit for determining a subcarrier with interference of a PRACH among subcarriers; An SRS puncturing unit for removing subcarriers based on subcarrier removal information received from the SRS puncturing control unit; And An SRS receiver including SRS signal detection and channel estimation for detecting a signal by fast Fourier inverse transform (IFFT) after zero padding and estimating a channel in consideration of the degree of cancellation. The method of claim 11, The interference data is timing information and PRACH reception power measured through the PRACH receiver, or the reception power of each subcarrier to which the PRACH measured by the SRS receiver itself is allocated. The method of claim 12, The SRS puncturing control unit estimates the interference amount of the PRACH overlapping the SRS by using the timing information measured and transmitted from the PRACH receiver and 'PRACH CINR information based on the PRACH reception power', and the estimated interference amount and the An SRS receiver for determining a subcarrier with interference of PRACH among the subcarriers of the SRS based on the received power or CINR of the SRS of the desired user provided from the CAZAC code compensation unit. The method of claim 12, After extracting the SRS subcarriers, the SRS puncturing control unit searches for a SRS reception signal of a desired user using CAZAC code-compensated information, examines the reception power or CINR of the corresponding SRS, and receives the reception power of each subcarrier to which a PRACH is allocated. And calculating a subcarrier with interference of the PRACH among the subcarriers of the SRS by comparing the calculated reception power and the average reception power of the SRS. The method according to any one of claims 11 to 14, When the SRS puncturing unit removes a subcarrier based on the subcarrier removal information, removes only a subcarrier to be removed, removes all portions of the SRS and PRACH overlapping in a frequency domain, or removes all received SRS signals. SRS receiver. The method of claim 15, The PRACH reception power is an average power value of each subcarrier to which a PRACH is allocated or one of individual power values of each subcarrier to which a PRACH is allocated.

Images