KR20170136255A - method for controlling RF channel simulator - Google Patents

Abstract

The present invention relates to a method for controlling a wireless channel simulator capable of: adopting an ADC having low resolution by adjusting a gain of an uplink signal receiving unit in the wireless channel simulator; extending a processible dynamic range of the uplink signal receiving unit; and providing an optimal simulation environment by adaptively adjusting the gain depending on a tested communication system or an operation environment. Provided is the method for controlling the wireless channel simulator capable of extending the dynamic range of the uplink signal receiving unit by adjusting the gain of the uplink signal receiving unit after determining the gain by inquiring path loss information, which is a simulation parameter, in a built PL-Gain table. The method for controlling the wireless channel simulator comprises the steps of: (a) determining the gain by inquiring a path loss in the PL-Gain table when an update event of the PL-Gain table is generated during an operation of the wireless channel simulator, and applying the determined gain to the uplink signal receiving unit; (b) measuring power of an uplink signal received from a terminal, and calculating compensation power (P_comp) by applying the measured power (P_meas) to reference power (P_ref) corresponding to an optimal quantization condition; and (c) updating the gain (G_n(k+1)) for the path loss of the PL-Gain table based on the compensation power (P_comp).

Description

A method for controlling a radio channel simulator,

The present invention is intended to provide a wireless channel simulator capable of expanding the processable dynamic range of the uplink signal receiving unit while adjusting the gain of the uplink signal receiving unit while adopting a low resolution ADC, The present invention relates to a control method of a radio channel simulator that can provide an optimal simulation environment by adaptively adjusting according to an operating environment.

Recently, as the information society is accelerating, researches on multimedia communication systems that simultaneously receive high-speed and high-quality voice and data through a wireless (RF) channel are actively conducted. On the other hand, mobile communication users are constantly demanding higher level of call quality, low error rate, and high data transmission speed, but it is very difficult to design a system required for a mobile communication channel.

In a multipath communication channel, a line of sight component, a reflected wave component, and a diffraction wave component are directly transmitted between a base station (BS) as a transmitter and a terminal (MS (Mobile Station) or UE (User Equipment) They exist at the same time, affecting each other. Since these signals are received by the terminal through multiple paths and Doppler spread by the movement of the terminal, it becomes a poor propagation environment compared with fixed communication.

Generally, a rural or suburban environment in which a direct path signal exists can be explained by a Rician channel model, and a composite signal by a multipath with a direct route is followed by a Rayleigh distribution. And there is a shading effect due to the nonuniformity of the surrounding terrain.

Since the radio environment in the wireless channel is very diverse, it is necessary to exercise the original performance of the wireless system in each different radio environment. Prototyping and field testing as well as verification through simulation and analysis are critical to ensure the performance of any wireless system. However, field testing of the developed wireless system in all environmental conditions is time consuming and costly, so the real-time wireless channel simulator is used in a more practical way. A wireless channel simulator is a system that can simulate almost any environment that may actually occur in a wireless (RF) channel (Implementation of a multipath fading channel simulator with a DSP-FPGA structure, Journal of the Acoustical Society of Korea, Vol. 23, (2004.1) pp.17-23, Lee, Ju-Hyun and others1).

On the other hand, fading mainly means spatial variation of signal strength, but may be regarded as temporal variation as the terminal moves. Such fading may include slow fading or long-term fading, in which the received signal strength varies slowly when the UE moves in a wide area, such as free space propagation loss (path loss) or shadow effect, and frequency selective fading or frequency non- There is fasting fading or short-term fading in which the strength of a received signal varies suddenly when a mobile station moves in a narrow region such as Doppler spreading fading. In a real environment, slow fading and fast fading overlap.

To implement the fading channel up to now, there are Okumura model which is the most widely used method to predict the signal in urban area, Hata model and Jake model which can be used both in the suburbs and open environments as well as in the inner city. In the case of slow fading, it is implemented by simply applying different delays to the start signal for each path, while in the case of fast fading, it is implemented by further multiplying the complex gain to slow fading. Finally, such slow fading and fast Fading are combined and output to the terminal or the base station.

Meanwhile, as a conventional method for simulating an actual channel environment in which a plurality of base stations and a plurality of terminals exist and mutually influence, a method of using a plurality of single radio channel simulators simulating a channel environment between one base station and one terminal However, there is a problem in that a great increase in cost due to duplication in function and a reduction in efficiency of space utilization have occurred. In order to solve this problem, the present applicant has applied for a patent for a large-capacity radio channel simulator configured to easily apply bidirectional path loss and bidirectional real-time fading to all paths (P * Q) between P base stations and Q terminals, Patent No. 1286023.

In general, a linear relationship is established between the path loss and the terminal transmission power, that is, when the path loss increases, the terminal transmission power also increases. On the other hand, when the path loss decreases, the transmission power of the terminal also decreases. Can be expressed as Equation (1).

은 단말의 송신 전력[dBm]이고,

은 기지국과 단말 간의 경로손실[dB]이며,

는 비례상수이고,

는 단말 송신 전력을 결정하는 그 외의 계수이다. 그리고 대부분의 이동통신 규격에서는 이러한 관계에 대한 구체적인 사항을 규정하고 있기 때문에 단말은 위 수학식 1에 의거하여 송신 전력을 결정한 후 업링크 신호를 송신한다.In Equation (1) above,

Is the transmission power [dBm] of the terminal,

Is the path loss [dB] between the base station and the terminal,

Is a proportional constant,

Is another coefficient for determining the terminal transmission power. Since most of the mobile communication standards prescribe specific details about this relationship, the terminal determines the transmission power based on Equation (1) and transmits the uplink signal.

Therefore, in constructing the uplink signal receiving unit of the large capacity radio channel simulator for 3GPP LTE system, it is required to be able to support the wide transmission power range of the UE according to the standard.

- Terminal minimum transmission power: -40dBm

- Terminal maximum transmission power: + 23dBm

- Signal to Quantization Noise Ratio (SQNR) / Error Vector Magnitude (EVM): 30 dB

- Support request transmission power range: + 23dBm - (-40dBm) + 30dB = 93dBm

Meanwhile, in a large capacity radio channel simulator, a digital signal processing method is also applied to obtain a channel fading effect. To this end, an uplink signal receiving unit is provided with an ADC for receiving an analog uplink signal transmitted from a terminal and converting it into a digital signal . An ADC for a modem or a small base station of such a terminal usually has a resolution of 12 bits. Assuming that the effective bit considering the noise level is 10 bits and has a dynamic range of 6.06 dB per bit, it is about 60 dB 10 * 6.06 dB). Therefore, assuming that SQNR is 30dB, a 12-bit ADC can handle only up to 30dB (60 - 30) dynamic range.

As a result, in order to support a wide transmission power range of about 90 dBm (considering SQNR) of WCDMA or LTE terminals, a high-performance ADC having a resolution of 16 bits to 17 bits per terminal must be provided in an uplink signal receiving unit of a large capacity radio channel simulator However, there has been a problem that the manufacturing cost of the wireless channel simulator increases dramatically.

In order to solve this problem, the applicant of the present invention has proposed a radio channel simulator that controls the gain of the uplink signal receiving unit so as to extend the processable dynamic range of the uplink signal receiving unit while adopting a low- Patent application No. 10-2015-0187820 (hereinafter referred to as "prior art 2").

More specifically, in the prior art 2, by adjusting the circuit gain or loss or the attenuation amount (referred to collectively as a gain) of the uplink by using the path loss information given as a simulation parameter to the channel simulator, Expanding its dynamic range. To this end, a gain table according to different path loss (hereinafter referred to as "PL-gain table") should be built in advance by simulation, testing or experience.

FIG. 1 is a block diagram for explaining the operation of the radio channel simulator disclosed in the prior art 2 of the present applicant, and shows a single channel simulator for convenience of explanation. 1, the wireless channel simulator disclosed in the prior art 2 of the present applicant is provided in an up-down converter of a terminal interface card (not shown) connected to the terminal 550 to set up (provide) an environment having a desired path loss, A channel simulation block 300 for providing a desired fading channel, an up-down converter (not shown) of a base station interface card (not shown) connected to the base station 500, an amplifier 44 and an A / D converter (DAC) 10 and a PL-gain table 70 described above.

In the above-described configuration, when the path loss of the radio channel simulator is determined, it is checked in the PL-Gain table 70 to check the corresponding gain, and then, based on this, the amplifier 44 of the terminal interface card up- The gain is automatically controlled. By this process, the power dynamic range of the input signal of the uplink signal receiving unit is reduced to a level sufficient for the ADC 42 having the 12-bit resolution.

On the other hand, the path loss value, which is different from the original demand value in accordance with the gain adjustment of the amplifier 44 of the up-converter, is transmitted to another part of the channel simulator, for example, the channel simulation block 30 or the up- It is restored to its original state by adjusting the amplifier gain.

와

값을 모르기 때문에 PL-Gain 테이블을 실험적인 경험치에 의해 만들 수밖에 없는데, 시험 대상인 이동통신 시스템의 종류 및 운영 환경마다

와

값이 다르다. 예를 들어 LTE 시스템의 경우,

는 네트워크로부터 SIB2(System Information Block 2)에 실려 브로드캐스트되며,

는 송신 신호의 대역폭(bandwidth), 목표 SINR(Signal-to-Interference-Plus-Noise Ratio) 또는 폐루프 파워 컨트롤(closed loop power control) 등 다양한 요인에 의해 결정된다.However, according to the control method of the conventional channel simulator as described above,

Wow

The PL-Gain table can not be created by the experiential experiential value because it does not know the value. In the case of the type of the mobile communication system and the operating environment

Wow

The values are different. For example, for LTE systems,

Is broadcasted from the network in SIB2 (System Information Block 2)

Is determined by various factors such as a bandwidth of a transmission signal, a target signal-to-interference-plus-noise ratio (SINR), or closed loop power control.

As a result, according to Prior Art 2 using a fixed PL-gain table which has been experimentally constructed conventionally in an arbitrary communication system and an operating environment, an optimal channel simulation environment is provided for communication systems and operating environments of various test objects There is a problem that it can not be done.

Prior Art 1: 10-1286023 (Patent Title: CHANNEL SIMULATOR) Prior Art 2: 10-2015-0187820 Patent Application (Name of invention: control method of channel simulator)

SUMMARY OF THE INVENTION The present invention is conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a radio channel simulator capable of expanding a processable dynamic range of an uplink signal receiving unit while adopting a ADC having a low resolution by adjusting a gain of an uplink signal receiving unit The present invention also provides a control method of a wireless channel simulator that can provide an optimal simulation environment by adaptively adjusting the gain according to a test target communication system or an operating environment.

In order to accomplish the above object, the present invention provides a method and apparatus for searching path loss information given as a simulation parameter in a PL-Gain (path loss vs. gain) table constructed in advance and determining a gain, A control method of a radio channel simulator for expanding a dynamic range of a signal receiving unit, the control method comprising the steps of: (a) querying a PL-gain table for a given path loss when an update event of a PL- Applying the determined gain to the uplink signal receiver after determining the gain; (b) measuring the power of the uplink signal received from the terminal, and applying the measured power (P _meas ) to a reference power (P _ref ) corresponding to an optimal quantization condition to calculate a corrected power (P _comp ) (c) updating the gain (G_n (k + 1)) for the corresponding path loss in the PL-gain table based on the correction power (P _comp ).

In the above-described configuration, the update event is generated when the characteristics of the uplink power control change during the period set by the user, the change of the communication system or the operating environment under test, or the simulation.

에 의해 산출되는 것을 특징으로 한다.The correction power (P _comp ) calculated in the step (b)

Is calculated by the following equation.

에 의해 구해지되, G_n(k)는 갱신 직전의 이득을 나타내고, k는 갱신 시마다 증가하는 타임 인덱스를 나타내며, μ는 적응 속도 및 안정성을 조절하는 파라미터로서 0~1 사이의 값으로 설정되는 것을 특징으로 한다.The gain G_n (k + 1) updated in the step (c)

(K) denotes a gain immediately before updating, k denotes a time index that increases with each update, and μ denotes a parameter for adjusting the adaptation speed and stability, which is set to a value between 0 and 1 .

According to the control method of the radio channel simulator of the present invention, the gain of the uplink signal receiving unit is adjusted in the radio channel simulator, especially in the large capacity radio channel simulator having P number of base stations and Q number of terminal interfaces, By expanding the possible dynamic range, it is possible to adopt an ADC having a low resolution, and thus the manufacturing cost of the large capacity channel simulator can be drastically reduced.

Further, even when the type or operating environment of the communication system to be tested is changed or the characteristics of the uplink power control change in the middle of the simulation, the optimum gain is derived through the adaptive learning, An optimal channel simulation environment can be provided by updating the PL-Gain table constructed as shown in FIG.

1 is a block diagram illustrating a control method of a radio channel simulator disclosed in the prior art 2 of the present applicant.
FIG. 2 is a block diagram of a large-capacity radio channel simulator disclosed in the prior art 1 of the present applicant.
3 is a block diagram of a large capacity radio channel simulator system in which a control method of the present invention is implemented;
4 is a conceptual diagram for explaining path loss in an uplink signal processing process in a large capacity radio channel simulator of the present invention.
5 is a block diagram illustrating a control method of a radio channel simulator according to the present invention.
6 is a flowchart for explaining a control method of a radio channel simulator according to the present invention;

Hereinafter, a preferred embodiment of a method of controlling a radio channel simulator of the present invention will be described in detail with reference to the accompanying drawings. First, a configuration of a large capacity radio channel simulator to which a control method of the present invention can be applied will be described.

FIG. 2 is a block diagram of a large capacity radio channel simulator disclosed in the prior art 1 of the present applicant. Only the uplink signal processing function related to the present invention will be described below. To-serial converters 130, 210, 220, 310, 330 and 410 which convert or convert the serial signals into parallel signals and vice versa, , 334, and 430 are excluded.

As shown in FIG. 2, the configuration of the large capacity radio channel simulator related to the uplink processing function is a one-to-one correspondence with the terminal, and includes a baseband signal obtained by down-converting an RF uplink signal input from a plurality of (Q) A terminal interface block 400 including a plurality of (Q) terminal interface cards 400-1 to 400-Q for outputting a plurality of terminal interface cards 400-1 to 400-Q. A plurality of (M) link processing groups 300-1, ..., 300-M having a plurality of front end input / output units 310, a plurality of link processors 320 and a plurality of rear end input / A link processing block 300 for performing fast fading and slow fading for each of a plurality of terminals after copying a plurality of baseband uplink signals output from the terminal interface block 400; Link processing block 300, only the uplink fading signals for all the uplink fading signals among all the uplink fading signals for the total Q terminals are integrated, and then the base station interface card 100- The distribution integration block 200 and the distribution integration block 200 each having a plurality of distributing / combining units 200-1, ..., 200-P for outputting a plurality of distributing / And a base station interface block 100 having a plurality of (P) base station interface cards 100-1,..., 100-P for up-converting the uplink fading signals to the corresponding base stations.

Reference numeral 110 denotes an up-down converter provided in each of the base station interface cards 100-1, ..., 100-P to perform up-conversion and down-conversion, and 420 denotes an up- ..., and 100-Q, and performs up-conversion and down-conversion.

3 is a block diagram of a large capacity radio channel simulator system in which the control method of the present invention is implemented. As shown in FIG. 3, the radio channel simulator system in which the control method of the present invention is implemented may include a massive air interface channel simulator (MAS) shown in FIG. Although not shown in FIG. 2, up-down converter 110 of each base station interface card (hereinafter, referred to as 'BS I / F card') 100-1 to 100- An Attenuator Att and an Amplifier and an A / D Converter ADC for performing A / D conversion are provided for a downlink channel (down converter) In addition, a D / A converter (DAC), an amplifier (Amp), and an attenuator (Att) are provided for the uplink channel (upconverter).

Similarly, an uplink converter 420 of each terminal interface card (hereinafter referred to as 'UE I / F card') 400-1 to 400-Q establishes (provides) (DAC), an amplifier (Amp), and an attenuator (Att) are provided for the downlink channel (up-converter), and attenuator Att, amplifier Amp and A / D conversion are performed An A / D converter (ADC) is provided for the uplink channel (down converter).

The configuration of the amplifier (Amp) and the attenuator (Att) of each of the up-down converters 110 and 420 can be achieved by configuring at least one of the amplifier Amp and the attenuator Att of the variable- In this case, a variable amplifier (Amp) and a variable attenuator (Att) having different power level adjustment resolutions may be used. Of course, it is also possible to configure the configuration consisting of the amplifier (Amp) and the attenuator (Att) combination of the up-down converters 110 and 420 as a single variable amplifier or a single variable attenuator.

3, the large capacity channel simulator system to which the method of the present invention is applied is connected to each of a plurality of BS I / F cards provided in the base station interface block 100 of the channel simulator (MAS) and the channel simulator (MAS) One to a plurality of UE I / F cards of a terminal interface block 400 of a plurality of, for example, P base stations (BSs) 500 and a channel simulator (MAS) A plurality of, for example, Q user equipments (UEs) 550 connected to one or more of the BS I / F cards 550, a channel simulator (MAS) (BS) control board 600 for adjusting the attenuation amount of the attenuator Att or the gain of the attenuator Att of each UE I / F card of the channel simulator (UE) control board 650, a user interface (UI) program And storing various scenario data set in the host PC 800 and the host PC 800, which are set in various scenarios such as a connection between the base station and the terminal and fading parameters between them, in a file form And a management server 700 for controlling the operation of the base station control board 600, the terminal control board 650, and the channel simulator (MAS) according to the scenario file.

In the above-described configuration, each of the one base station control board 600 and the one terminal control board 650 may have a plurality of, for example, 12 BS I / F cards and 12 UE I / F cards. The management server 700 stores the A / D conversion data (hereinafter, referred to as 'ADC data') of the BS I / F card or the calibration data thereof in association with the path loss calibration and transmits the calibration data to the base station control board 600 Command, that is, the gain of the amplifier (Amp) of the BS I / F card or the attenuation amount adjustment command of the attenuator (Att). The management server 700 also collects a DM (Diagnostic Monitoring) message from each terminal and then sends a calibration command to the terminal control board 650, that is, a gain of the amplifier Amp of the UE I / F card, ) Can be issued. The management server 700 can also implement a fading channel in units of 1 ms in real time, for example, in the LTE system by controlling the link processor of the channel simulator (MAS) based on the scenario file. The host PC 800, the management server 700, the base station control card 600, and the terminal control card 650 may be connected to each other via Ethernet.

4 is a conceptual diagram for explaining path loss in an uplink signal processing process in a large capacity radio channel simulator of the present invention. As shown in FIG. 4, the path loss in the process of uplink signal processing in the large capacity radio channel simulator, that is, the total path loss PL from the UE to the base station BS, path loss in the cable connecting the UE I / F card (b'd UE) of a radio channel simulator, the terminal (CL _ue), the path loss in the radio channel simulator as internal (G _sys; expressed as gain) and a channel simulator, (CL _bs ) in a cable connecting a base station (BS) to a base station (BS).

On the other hand, the path loss (G _sys ) in the radio channel simulator is calculated by multiplying the gain (G _ad ) of the UE I / F card UE b'd, the gain (G _da ) of the BS I / F card ) And the gain (G _d ) of the link processing block (DM / LP). According to this structure, by appropriately adjusting the gain of the UE I / F card (UE b'd), the BS I / F card (BS b'd) or the link processing block (DM / LP) of the radio channel simulator, Can be set to a desired value.

Table 1 below is a table showing the PL-Gain table exemplified in Prior Art 2. It is constructed based on the log data of the path loss versus UE transmission power (UE Tx power) for the uplink signal collected by driving the channel simulator .

Pass Loss (dB) Gain (dBm) 45 0 50 2 55 3.5 60 5 65 7.5 70 10 75 13 80 17 85 21 90 25 95 30 100 34

FIG. 5 is a block diagram for explaining a control method of the radio channel simulator of the present invention, and shows a single-channel simulator for convenience of explanation. 5, the wireless channel simulator of the present invention is provided in an up-down converter of a terminal interface card (not shown) connected to the terminal 550 to support setting (providing) an environment having a desired path loss A channel simulating block 300 for providing a desired fading channel and a D / A converter (not shown) provided in an up-down converter of a base station interface card (not shown) connected to the base station 500, A converter (DAC) 10, a PL-gain table 70 'that is updated each time it is updated, a power measuring unit 72 and a power measuring unit 72 that measure the output terminal power of the A / D converter 42 After calculating the correction power P _comp according to the result of comparing the measured power P _{meas with} the reference power P _ref corresponding to the optimal quantization condition, And a gain updating unit (74) for updating a gain value for loss. It can be done.

6 is a flowchart for explaining a control method of the radio channel simulator of the present invention. As shown in FIG. 6, in step S10, it is determined whether or not a PL-Gain table update event has occurred during the operation of the wireless channel simulator. The update event includes a period set by the user, Or when the characteristics of the uplink power control change in the middle of the simulation.

If it is determined in step S10 that an update event has occurred, steps S20 and S30 are performed to determine a corresponding gain by querying the given path loss in the PL-Gain table and apply it to the uplink signal receiving unit, ).

Next, in step S40, the power of the uplink signal received from the terminal 550 is measured. In step S50, the measured power P _meas is applied to the reference power P _ref corresponding to the optimal quantization condition, (P _comp ), and this correction power can be calculated by the following equation (3).

Finally, in step S60, the gain for the corresponding path loss in the PL-gain table is updated on the basis of the correction power. This gain G_n (k + 1) can be determined by the following equation (4).

In Equation (4), G_n (k) represents a gain immediately before updating, k represents a time index that increases with each update, and μ is a parameter for adjusting the adaptation speed and stability and is set to a value between 0 and 1 .

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Accordingly, the scope of the present invention should be determined by the following claims.

100: base station interface block, 100-1, ... , 100-P: base station interface card,
200: distribution / integration block, 200-1, ... , 200-P: distribution / integration card,
300: link processing block, 300-1, ... , 300-M: link processing group,
310: front end input / output unit, 320: link processor,
330: rear end input / output unit, 400: terminal interface block,
400-1, ... , 400-Q: terminal interface card,
500: base station control board, 550: terminal control board,
600: base station, 650: terminal,
700: management server, 800: host PC

Claims (4)

A path loss information given as a simulation parameter is retrieved from a PL-Gain (path loss vs. gain) table constructed in advance and the gain is determined. Thereafter, the gain of the uplink signal receiving unit is adjusted to increase the dynamic range of the uplink signal receiving unit. In the control method of the simulator,
(a) querying a PL-Gain table for a given path loss when a PL-Gain table update event occurs during operation of the wireless channel simulator, determining a corresponding gain, and then applying the determined gain to an uplink signal receiver;
(b) measuring the power of the uplink signal received from the terminal, and applying the measured power (P _meas ) to a reference power (P _ref ) corresponding to an optimal quantization condition to calculate a corrected power (P _comp )
(c) a step of updating a gain (G_n (k + 1)) for the corresponding path loss in the PL-gain table based on the correction power (P _comp ) . The method according to claim 1,
Wherein the update event occurs when the characteristics of the uplink power control change during the period set by the user, the change of the communication system under test, the operating environment, or the simulation. 3. The method of claim 2,
The correction power (P _comp ) calculated in the step (b)

And wherein the radio channel simulator is a radio channel simulator. 4. The method according to any one of claims 1 to 3,
The gain G_n (k + 1) updated in the step (c)

Lt; / RTI >
Wherein G_n (k) represents a gain immediately before updating, k represents a time index that increases with each update, and [mu] is a parameter for adjusting the adaptation speed and stability and is set to a value between 0 and 1. [ / RTI >

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