KR101517539B1 - Method for interfacing between link level and system level, and simulator apparatus thereof - Google Patents

Abstract

In order to analyze the performance of a wireless communication system, when the same power is allocated to all the codes for users in a cell at a link level, the power allocated to users communicating the obtained link level simulation results in the same cell The present invention relates to a method for interfacing between a link level and a system level and a simulator device for preventing errors due to mismatch of power values when applied to different system level simulations,

An interface method between a link level and a system level according to the present invention comprises the steps of: (a) measuring received power at a system level; (b) calculating a power ratio (Ior / Ioc) using the measured received power; And (c) referring to the block error rate (BLER) of the link level to which the calculated power ratio (Ior / Ioc) is applied.

Link level, system level, simulation, joint detection, BLER, error rate, Ioc, Ior, interference, noise, TD-SCDMA

Description

TECHNICAL FIELD [0001] The present invention relates to an interface method between a link level and a system level, and a simulator apparatus therefor.

The present invention relates to a method for interfacing between a link level and a system level and a simulator apparatus thereof. More particularly, the present invention relates to a method for interfacing between a link level and a system level, A link-level and system-level interface method for preventing a link-level simulation result from generating an error due to a mismatch of power values when power allocated to users communicating in the same cell is applied to different system-level simulations; and And a simulator device.

In general, performance analysis of a wireless communication system can be broadly divided into link level simulation and system level simulation. Link level simulation shows the performance result according to various wireless communication channel environment as a BLER (Block Error Rate) curve.

The ideal link-level simulation is to analyze and store all the performance results for all possible cases. However, since this is not practicable, a BLER curve according to the signal-to-interference and noise ratio (SINR) We calculate the SINR of each user over time in the system level simulation and perform the performance analysis based on the link level simulation result curve.

Meanwhile, interference in a cellular wireless communication system can be divided into inter-cell interference and intra-cell interference. Intracell interference indicates a case where signals for users communicating in the same cell act as interference with each other. Intercell interference indicates a case where a signal for communication in the neighboring cells acts as interference. The effect of each interference on performance varies depending on the transmission and reception stage structure.

The TD-SCDMA system is a time-division synchronous code division multiple access scheme with a chip rate of 1.28M chips per second, and performs joint detection at the receiving end to minimize intra-cell interference. That is, the influence of the intra-cell interference on the performance is different by joint detection. Therefore, the influence of joint detection should be considered for proper performance analysis.

In general, the performance at the link level is given by the BLER curve according to Ior / Ioc. Here, Ior represents the total power of the serving base station, and Ioc represents the total power of adjacent cell interference and white noise AWGN noise. That is, Ior includes not only the power of a signal to be received but also intra-cell interference. At the link level, it is assumed that the code-by-code power allocation for users in a cell is the same. That is, BLER performance for Ior / Ioc is measured when Joint Detection is applied on the assumption that the same power is allocated to all codes.

However, the assumption that the same amount of power is allocated to each code in the link level simulation is not appropriate in a real system level simulation. This is because, in the system level simulation, the power control is performed according to the position of the terminal for each user, and the actual power allocated to the users communicating in the same cell at the same time is different from each other.

Therefore, it is not appropriate to apply the link level performance analysis results obtained by assuming that the power allocated to different codes is the same. A new analytical methodology is needed to overcome the errors caused by these inconsistencies, and the analysis has not been done in the past

In order to solve the above-mentioned problems and to meet the requirements, the present invention is characterized in that when the same power is allocated to all codes for users in a cell at a link level for performance analysis of a wireless communication system, A method for interfacing between a link level and a system level and a simulator device for preventing an error caused by a mismatch of power values when power allocated to users communicating in a cell is applied to different system level simulations, There is a purpose.

According to an aspect of the present invention, there is provided a method for interfacing between a link level and a system level, comprising the steps of: (a) measuring received power at a system level; (b) calculating a power ratio (Ior / Ioc) using the measured received power; And (c) referring to the block error rate (BLER) of the link level to which the calculated power ratio (Ior / Ioc) is applied.

In step (a), the received power includes received power of a signal to be received, received power of intra-cell interference, and received power of inter-cell interference for each user.

In the step (b), the total power of the serving base station is divided by the adjacent cell interference and the total power of noise (Ioc) to calculate the power ratio.

The total power of the serving base station is calculated by adding the sum of the intra-cell interference to the sum of the received power of the codes to be received.

Also, the total power of the adjacent cell interference and noise is calculated by adding the noise power level to the total sum of the interference from the adjacent cell.

In the step (c), the total received power of the serving base station is obtained by multiplying the ratio between the total number of codes and the number of codes to be received by the sum of the received powers of the codes to be received. At this time, the ratio is calculated by dividing the total number of codes 16 by the number of codes to be received.

And, in the step (c), additional interference is added to the total power of adjacent cell interference and noise to obtain the total interference noise power. At this time, the additional interference is obtained by subtracting the total received power from the total power of the serving base station, and then multiplying by the interference reflection constant (?) For joint detection.

According to another aspect of the present invention, there is provided a simulator apparatus for calculating a power ratio using received power, interference, and noise power of a signal including a midamble of each mobile station, (BLER); < / RTI > A controller for measuring the received power and the interference and noise power, calculating the power ratio therefrom, and analyzing performance of a wireless communication channel with reference to the block error rate (BLER); A display unit for displaying a result of performance analysis of the wireless communication channel; And a link level simulator for calculating the block error rate (BLER) curve according to the power ratio and applying the result to the system level simulator.

The system level simulator may further include: a power measuring unit for measuring a received power of a received signal for each user, a received power of intra-cell interference and a received power of inter-cell interference with respect to signals of the respective mobile stations; A power ratio calculating unit for calculating a power ratio by applying noise power to the measured received power to divide the total power (Ior) of the serving base station by the adjacent cell interference and the total power (Ioc) of noise; And an error rate reference unit for referring to the block error rate (BLER) to which the calculated power ratio Ior / Ioc is applied.

The power ratio calculator calculates the total power of the serving base station by adding the sum of intra-cell interference to the sum of received powers of codes to be received.

The power ratio calculator calculates a total power of the adjacent cell interference and noise by adding a noise power level to the total sum of the interference from the adjacent cells.

The error rate reference unit obtains the total received power of the serving base station by multiplying the ratio between the total number of codes and the number of codes to be received by the sum of the received powers of the codes to be received. At this time, the ratio is calculated by dividing the total number of codes 16 by the number of codes to be received.

Then, the error rate reference unit adds additional interference to the total power of neighboring cell interference and noise to obtain the total received noise interference power. Here, the additional interference is obtained by subtracting the total received power from the total power of the serving base station, and then multiplying the received interference power by the interference reflection constant for the joint detection.

According to another aspect of the present invention, there is provided a simulator apparatus comprising: an input unit receiving a signal including a midamble; A simulator for referring to a block error rate (BLER) using received power of the input signal and interference and noise power; And a controller for analyzing performance of the wireless communication channel with reference to the block error rate (BLER).

The simulator may further include: a system level simulator for calculating a power ratio using received power, interference and noise power of the input signal, and referring to a block error rate (BLER) to which the power ratio is applied; And a link level simulator for calculating the block error rate (BLER) curve according to the power ratio and applying the result to the system level simulator.

The system level simulator may further include: a power measuring unit for measuring received power of a received signal for each user, received power of intra-cell interference and received power of inter-cell interference with respect to the received signal of each mobile station; A power ratio calculator for calculating a power ratio by applying noise power to the measured received power to divide the total power of the serving base station by the total power of adjacent cell interference and noise; And an error rate reference unit for referring to the block error rate (BLER) to which the calculated power ratio is applied.

The power ratio calculator calculates the total power of the serving base station by adding the sum of intra-cell interference to the sum of received powers of codes to be received.

The power ratio calculator calculates a total power of the adjacent cell interference and noise by adding a noise power level to the total sum of the interference from the adjacent cells.

The error rate reference unit obtains the total received power of the serving base station by multiplying the ratio between the total number of codes and the number of codes to be received by the sum of the received powers of the codes to be received. At this time, the ratio is calculated by dividing the total number of codes 16 by the number of codes to be received.

Then, the error rate reference unit adds additional interference to the total power of neighboring cell interference and noise to obtain the total received noise interference power. Here, the additional interference is obtained by subtracting the total received power from the total power of the serving base station, and then multiplying the received interference power by the interference reflection constant for the joint detection.

According to the present invention, more accurate analysis results can be obtained by suitably applying the effect of intra-cell interference and joint detection occurring on the TD-SCDMA system level simulation.

In addition, instead of applying the power ratio Ior / Ioc applied with the total power Ior of the serving cell, the total received power Ior 'and the total power Ioc ) Can be more accurately analyzed by referring to the BLER value through Effective Ior / Ioc.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically illustrating a configuration of a simulation to which an interface method between a link level and a system level is applied according to an embodiment of the present invention.

Referring to FIG. 1, the configuration of a simulation according to the present invention includes mobile stations (MS) 110 to 116 and base stations 120 to 124.

Here, the first mobile station 110 and the second mobile station 112 are located in the reference cell of the first base station 120 and the third mobile station 114 is located within the reference cell of the second base station 120 122 and the fourth mobile station 116 is located in a cell of the third base station 124 that is adjacent to the first base station 120. [

The mobile stations 110 to 116 transmit signals including the midambles to the base stations 120 to 124 and receive system information from the base stations 120 to 124.

The base stations 120 to 124 measure the received power of a signal to be received for each user, the received power of intra-cell interference and the received power of inter-cell interference, apply the measured received power and the noise power, The power (Ior) is divided by the total power (Ioc) of adjacent cell interference and white Gaussian noise, and the performance is analyzed with reference to BLER (Block Error Rate) by applying this calculation.

The first base station 120 transmits a signal including the midamble from the first mobile station 110 and the second mobile station 112 in the reference cell area and from the third mobile station 114 and the fourth mobile station 116 in the adjacent cell area And combines the first midamble of the first mobile station with the second midamble of the second mobile station, the midamble of the third mobile station and the midamble of the fourth mobile station to generate a midamble matrix G. [

Then, the first base station 120 multiplies the generated midamble matrix G by a pseudo inverse matrix to generate a combined channel of the first mobile station 110 and the second mobile station 112 located in the reference cell, Obtain an estimate.

The first base station 120 calculates a system matrix of a reference cell and neighbor cells using each channel estimation value and a spreading code and calculates a system matrix A ₀ of a cell of the first base station 210, (D ₀ ) by multiplying the system matrix combining the system matrix A _{1 of the first} cell 212 and the system matrix A ₂ of the cell of the third base station 214 by the pseudoinverse matrix do.

On the other hand, in the mobile communication system, the actual base stations 120 to 124 are arranged in units of cells, and a call request generated in the mobile stations 110 to 116 is transmitted to the MSC, And performs location registration for grasping the location of the mobile stations 110 to 116 existing in the mobile station 110. [

The base stations 120 to 124 include a base transceiver station (BTS) and a base station controller (BSC). The mobile communication system includes a mobile station controller (MSC) and a home location register Hereinafter referred to as HLR), but this is not shown and is omitted because it corresponds to a conventional technique.

The base station transmitter (BTS) obtains information such as the latitude and longitude of the base station transmitter (BTS) from the GPS (Global Positioning System) and transmits the system parameter message of the downlink paging channel to the position information of the base station transmitter To the mobile stations (110 - 116). The mobile stations 110 to 116 can register new location information by calculating the movement distance of the mobile stations 110 to 116 using the location information of the base transceiver station (BTS) of the cell to which the mobile stations 110 to 116 belong.

The location registration is a processing procedure for notifying the MSC of the location, state, identifier, slot period, and other characteristics of the mobile stations 110 to 116 via the corresponding base transceiver station (BTS), wherein the base transceiver station (BTS) To effectively call the mobile stations 110 to 116 when it is desired to set up an incoming call. The location registration of the mobile stations 110 to 116 is performed when the mobile stations 110 to 116 are powered on or off, when the mobile stations 110 to 116 move between the MSCs, and when the parameters of the mobile stations 110 to 116 are changed .

The base station controller (BSC) controls and manages a plurality of base stations 120 to 124 and performs various functions necessary for radio call processing such as handoff. Also, the base station controller BSC transmits the subscriber information of the mobile stations 110 to 116 registered in the location to the MSC.

The MSC has a control function that enables efficient operation of wireless base stations and a function of interworking with the exchange of the public telephone network. When the location registration of the mobile stations 110 to 116 is performed through the wireless base station, the MSC temporarily stores subscriber information of the mobile stations 110 to 116 in the Visitor Location Register (VLR) in the MSC, The location registration of the mobile stations 110 to 116 is requested.

Here, the HLR is a database storing a service profile related to subscriber information of a user of the mobile stations 110 to 116, and includes a mobile identification number (MIN) of the mobile stations 110 to 116, An electronic serial number (ESN), and a service type. The HLR functions to store subscriber information including information on the MSCs and base stations 120 to 124 where the mobile stations 110 to 116 are located. The MSC is composed of a control unit, a communication unit and a peripheral device, and also has an accounting data collecting function for the mobile stations 110 to 116.

Meanwhile, the mobile communication network includes a mobile communication network such as a CDMA (Code Division Multiple Access), a WCDMA (Wideband Code Division Multiple Access), a HSDPA (High Speed Downlink Packet Access) WiBro: wireless broadband).

2 is a diagram illustrating a configuration of a radio frame as a basic unit of radio transmission in a TD-SCDMA mobile communication network to which the present invention is applied.

Referring to FIG. 2, the radio frame is composed of two sub-frames each having a length of 5 ms, and constitutes a basic unit of radio transmission having a length of 10 ms. The subframe consists of 7 time slots (Timeslot), DwPTS 202 and UpPTS 205.

In FIG. 2, a time slot indicated by an arrow is a downlink transmission interval for transmitting a signal from a base station to a mobile station, and a time slot indicated by an arrow is an uplink for transmitting a signal from a mobile station to a base station ) Transmission interval.

In the TD-SCDMA mobile communication network, since the uplink transmission interval and the downlink transmission interval are changed in time slot unit, some rules are applied to allocate the time slots of the subframe to the uplink / downlink transmission interval.

2, the time slot 0 (201) must be used only for downlink transmission, and the DwPTS 202 is a period for transmitting a preordained code sequence from the base station so that the mobile station can synchronize. The base station 205 transmits a specific code sequence pre-assigned to the base station by the mobile station for reverse synchronization.

The switching period 203 indicates a time point when the uplink / downlink transmission is changed. The guard period (GP) 204 overlaps the DwPTS 202 and the UpPTS 205 to give interference to each other It is a section to set to avoid. The switching point 203 sets a large number of uplink timeslots when there is a large amount of data to be transmitted upward and a large number of downlink time slots when a large amount of data to be transmitted is downlinked.

3 is a diagram showing a structure of a time slot in a subframe.

3, a time slot in a subframe includes data symbols 302 and 306, a midamble 304, and a GP 308. [

The data symbols 302 and 306 are used for uplink transmission and downlink transmission. The midamble 304 is used to distinguish channels of a mobile station or a base station using the same time slot in uplink transmission.

In addition, the midamble 304 measures the channel estimation in uplink and downlink transmission, and the loss due to the channel path from the base station to the mobile station in downlink transmission. Each base station uses a different midamble so that the midamble is used to distinguish the base station. The midamble 304 uses a specific sequence, and there are 128 types in a specific sequence. The channel codes and the midamble sequences used in the midamble are different in characteristics and types. For example, the channel code used in the uplink transmission is an orthogonal code used for the data symbols 302 and 306, and serves to distinguish data of mobile stations that transmit data through the data symbols 302 and 306.

The GP 308 serves to distinguish between the currently transmitted time slot and the next transmitted time slot. The GP 308 performs a downlink transmission time slot after the uplink transmission time slot, It is possible to distinguish the interference signals from each other.

4 is a block diagram showing an internal configuration of a simulator device to which the present invention is applied, as functional blocks.

4, the simulator apparatus 400 to which the present invention is applied includes a signal input unit 410, a power measurement unit 420, a power ratio calculation unit 430, an error rate reference unit 440, a control unit 450, Level simulator 460 and a display unit 470. [

The power measurement unit 420, the power ratio calculation unit 430, and the error rate reference unit 440 form a system level simulator.

The signal input unit 410 receives a signal including a midamble of each of the mobile stations 110 to 116 from a user or an administrator.

The power measuring unit 420 measures the received power of the received signal for each user, the received power of the intra-cell interference, and the received power of the inter-cell interference with respect to the signals of the respective mobile stations 110 to 116.

The power ratio calculating unit 430 calculates the power ratio by applying the noise power to the measured received power to divide the total power Ior of the serving base station by the total power Ioc of the adjacent cell interference and the white Gaussian noise (AWGN) .

The error rate reference unit 440 refers to the BLER by applying the calculated power ratio (Ior / Ioc).

The control unit 450 measures the received power of the received signal, the received power of the intra-cell interference and the received power of the inter-cell interference, calculates the power ratio with respect to the total power to noise, Performance will be analyzed.

The link level simulator 460 calculates a BLER curve according to the power ratio (Ior / Ioc) and applies the result to the error rate reference unit 440.

The display unit 470 displays the operation status of the apparatus or the result of the performance analysis of the wireless communication channel.

5 is a flowchart illustrating an interface method between a link level and a system level according to an embodiment of the present invention.

According to the present invention, instead of applying the Ior / Ioc applied with the Ior representing the total power of the serving base station cell, the power ratio (Ior / Ioc) applied with Ior and Ioc appropriately applied intra-cell interference included in the total power of the serving base station cell, So that more accurate performance analysis can be performed by referring to the BLER value.

5, the simulator apparatus 400 receives a signal including a midamble for each of the mobile stations 110 to 114 in the reference cell and neighboring cells through the signal input unit 410 (S510).

The simulator apparatus 400 measures the reception power of the reception signal for each user, the reception power of the intra-cell interference and the reception power of the inter-cell interference through the power measurement unit 420 based on the signal including the received midamble (S520).

Next, the simulator apparatus 400 calculates the power ratio Ior / Ioc by applying the noise power to the measured received power through the power ratio calculating unit 430 (S530).

The calculation of Ior and Ioc according to the present invention is calculated using the received signal level from the serving cell, the total signal level from the adjacent cell, and the noise power for each code.

Ior is the total received power received from the serving cell through a total of 16 code resources used in the TD-SCDMA. If the average received power of each code is Po, the following Equation 1 is established.

는 수신하고자 하는 코드들의 수신 전력의 합을 나타내고,

는 셀 내 간섭의 총 합을 나타내며, n은 해당 서비스를 위해 사용되는 코드의 수를 나타낸다. here,

Represents a sum of received powers of codes to be received,

Represents the total sum of intra-cell interference, and n represents the number of codes used for the corresponding service.

Therefore, the simulator apparatus 400 calculates the power ratio Ior / Ioc by the following equation (2).

는 인접 셀로부터의 간섭의 총 합을 나타내고,

은 잡음 전력 레벨을 나타내며,

는 간섭잡음의 총 전력을 나타낸다.here,

Represents the total sum of the interference from the adjacent cell,

Represents the noise power level,

Represents the total power of the interference noise.

,

각각의 값이 아닌 두 값의 합에 의해 결정된다. 하지만

가 클수록 성능은 좋아지고,

가 작을수록 성능이 좋아진다. Ioc / Ioc, calculated as Equation 2,

,

It is determined by the sum of two values, not each value. However

The higher the performance, the better the performance.

The smaller the value, the better the performance.

If the same power is assigned to each code, if the performance is determined by the sum of the two values, it can be applied because it will be consistent with the link level simulation result.

However, since the power allocated to each code differs according to the power control for each user, actual system level simulation has different performance depending on the received signal level and intra-cell interference even though the same Ior value is used.

Then, the simulator apparatus 400 refers to the BLER by applying the calculated power ratio Ior / Ioc to the error rate reference unit 440 as shown in Equation 2 (S540).

/n 만큼의 전력이 할당되었다고 가정했을 경우 16 개의 코드의 총 전력을 총 수신전력 Effective Ior(

)라고 정의하며 다음 수학식 3과 같이 계산한다.In order to obtain a more appropriate BLER, the simulator apparatus 400 may be configured such that the serving base station

/ n is allocated, the total power of the 16 codes is calculated as the total received power Effective Ior (

) And is calculated according to the following equation (3).

는 전체 코드 수 16과 수신하고자 하는 코드 수 n 간의 비율을 나타내며 다음 수학식 4와 같이 정의한다.here,

Represents the ratio between the total number of codes 16 and the number n of codes to be received, and is defined as the following Equation 4. " (4) "

중

을 제외한 전력을 '추가적인 간섭'이라 정 의한다. 이는 Effective Ior을 적용했을 때 셀 내 간섭 중 링크 레벨 시뮬레이션에서 고려되지 못한 셀 내 간섭을 나타낸다. 즉, 수신하고자 하는 신호 레벨

값에 기반하여 계산된

을 총 수신 전력이라 가정하고 이 값이 실제 측정된

과 같다면 이는 링크 레벨 시뮬레이션 결과에 적용이 가능하다. The total power of the base station

medium

Is defined as 'additional interference'. This indicates intra-cell interference when the Effective Ior is applied, which is not considered in the link level simulation. That is, the signal level

Calculated based on the value

Is assumed to be the total received power, and this value is actually measured

, It can be applied to link level simulation results.

이 실제 측정된

과 다르다면 이는 링크 레벨에서 가정했던 것 보다 셀 내 간섭이 크거나 작음을 나타낸다. 그러므로 '추가적인 간섭'이 커질수록 성능이 열화된다. However,

This actual measured

, This indicates that the intra-cell interference is larger or smaller than that assumed at the link level. Therefore, the larger the 'additional interference', the worse the performance.

6 is a diagram showing the relationship between the sum of the received power according to the total power of the base station and the total received power and the code. 6A shows a case where the total power Ior is equal to the total received power Ior 'and FIG. 6B shows a case where the total received power Ior' is larger than the total power Ior of the base station (C) shows a case where the total received power (Ior ') is smaller than the total power (Ior) of the base station.

The received interference noise total power Effective Ioc is calculated as shown in Equation (5) in consideration of 'additional interference'.

에 일정량의 간섭이 추가된 것으 로 가정하고, 만일 추가적인 간섭이 0보다 작으면 마치

에 일정량의 간섭이 제거된 것으로 가정한다. 여기서, α는 결합 검출(Joint Detection)에 대한 간섭 반영 상수로서 0 과 1 사이의 실수 값을 갖는다. That is, if the additional interference is greater than 0,

, And if the additional interference is smaller than 0,

It is assumed that a certain amount of interference has been removed. Here, a is an interference reflection constant for joint detection, and has a real value between 0 and 1.

Therefore, the Effective Ior / Ioc using Effective Ior and Effective Ioc is calculated as shown in Equation (6) through the error rate reference unit (440).

The simulator apparatus 400 applies the effective Ior / Ioc calculated as shown in Equation (6) to the BLER Curve as a result of the link level simulation performance analysis of the link level simulator 460 through the error rate reference unit 4400, The BLER value can be obtained which appropriately reflects the effect of the detection.

Therefore, the simulator apparatus 400 can easily perform the performance analysis of the radio channel using the BLER value.

As described above, according to the present invention, when the same power is allocated to all the codes for users in a cell at a link level in order to analyze the performance of a wireless communication system, Level system and the simulator device so that an error due to a mismatch of power values is not generated when the power allocated to the system level simulation is applied to different system level simulations.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims and their equivalents. Only. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

The present invention can be applied to a mobile communication system requiring analysis of the performance of a wireless channel and to an algorithm requiring an interface between a system level simulation and a link level simulation.

In addition, a BLER curve according to the signal-to-interference-and-noise ratio (SINR) is stored as a link level simulation result, a simulation is performed to calculate the SINR of each user over time in the system level simulation, Device.

The present invention can also be applied to a simulation of a cellular wireless communication system in which inter-cell interference and inter-cell interference occur.

1 is a diagram schematically illustrating a configuration of a simulation to which an interface method between a link level and a system level is applied according to an embodiment of the present invention;

2 is a diagram illustrating a configuration of a radio frame, which is a basic unit of radio transmission in a TD-SCDMA mobile communication network to which the present invention is applied,

3 is a diagram showing a structure of a time slot in a subframe,

4 is a block diagram showing the internal structure of a simulator device to which the present invention is applied,

5 is a flowchart illustrating an interface method between a link level and a system level according to an embodiment of the present invention; and

6 is a diagram showing the relationship between the sum of the received power according to the total power of the base station and the total received power and the code.

Description of the Related Art

110 to 116: mobile stations 120 to 124: base stations

410: communication unit 420: power measurement unit

430: Power ratio calculating unit 440: Error rate reference unit

450: control unit 460: link level simulator

Claims (26)

(a) measuring received power at a system level; (b) calculating a power ratio (Ior / Ioc) using the measured received power; And (c) the ratio between the total number of codes and the number of codes to receive

), The sum of the received powers of the codes to be received (

) To obtain the total received power (Ior ') of the serving base station and obtain additional received interference noise total power (Ioc') by adding additional interference to the total cell power (Ioc) of the adjacent cell interference and noise, (IOR '/ Ioc') of the received interference noise total power (Ioc ') and the block error rate (BLER) of the link level through the power ratio Ior' / Ioc ' The link level and the system level. The method according to claim 1, In step (a), the received power includes a received power of a signal to be received for each user, a received power of intra-cell interference, and a received power of inter-cell interference. . The method according to claim 1, Wherein the step (b) calculates the power ratio (Ior / Ioc) by dividing the total power (Ior) of the serving base station by the adjacent cell interference and the total power (Ioc) of the noise. Interface method. The method of claim 3, The total power (Ior) of the serving base station is a sum of received powers of codes to be received

) To the total sum of intra-cell interference

) To the link level and the system level. The method of claim 3, The total power (Ioc) of the adjacent cell interference and noise is calculated by summing the sum of the interference

) To the noise power level (

) To the link level and the system level. delete delete delete The method according to claim 1, Characterized in that the further interference is obtained by subtracting the total received power (Ior ') from the total power (Ior) of the serving base station and then multiplying by the interference reflection constant (?) For joint detection. A power measuring unit for measuring received power of a received signal for each user, received power of intra-cell interference and received power of inter-cell interference with respect to a signal of each mobile station; A power ratio calculating unit for calculating a power ratio by applying noise power to the measured received power to divide the total power (Ior) of the serving base station by the adjacent cell interference and the total power (Ioc) of noise; And An error rate reference unit which refers to a block error rate (BLER) to which the calculated power ratio Ior / Ioc is applied; / RTI > The error rate reference unit, The ratio between the total number of codes and the number of codes you want to receive (

), The sum of the received powers of the codes to be received (

) To obtain the total received power (Ior ') of the serving base station, add the additional interference to the total cell power (Ioc) of the adjacent cell interference and noise to obtain the received interference noise total power (Ioc'), (BLER) of the link level through the power ratio (Ior '/ Ioc') of the received interference noise total power (Ioc ') and the received interference noise total power (Ioc'). delete 11. The method of claim 10, The power ratio calculator calculates a sum of received powers of codes to be received

) To the total sum of intra-cell interference

) Is added to calculate the total power (Ior) of the serving base station. 11. The method of claim 10, The power ratio calculator calculates a sum of interference from adjacent cells (

) To the noise power level (

) Is added to calculate the total power (Ioc) of the adjacent cell interference and noise. delete delete delete 11. The method of claim 10, Wherein the further interference is obtained by subtracting the total received power (Ior ') from the total power (Ior) of the serving base station and then multiplying by the interference reflection constant (?) For joint detection. delete delete delete delete delete delete delete delete delete

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