KR100958820B1 - Terminal device emulator and Method for measuring the performance of a base station using the emulator - Google Patents

Abstract

The present invention is for measuring a base station. More specifically, a single terminal emulator physically receives a plurality of CIDs (Connection IDs) and transmits each measurement message to the same UL resource by using a MIMO scheme. The present invention relates to a terminal emulator capable of acting as a plurality of emulators by receiving a message and a base station performance measuring method using the same.

Accordingly, the terminal emulator according to the present invention manages a plurality of CIDs (Connection IDs) allocated from the base station, generates a test message including each CID, and transmits the same to the base station through the same UL (Up Link) resource. A response message corresponding to the message is received to measure the performance of the base station, and the measurement result is provided.

Therefore, a plurality of terminals are required by receiving a plurality of CIDs as a base station, transmitting a test message including each CID to the base station through the same UL resource, and receiving a corresponding response message to measure the performance of the base station. There is an advantage in that it is possible to measure the performance of a base station supporting cooperative MIMO using a single physical terminal emulator.

 Mobile WiMAX, IEEE 802.16e, 3GPP LTE, Collaborative MIMO, Packet Error Rate, UL / DL MAP

Description

Terminal emulator and method for measuring the performance of a base station using the emulator}

The present invention is for measuring a base station. More specifically, a single terminal emulator physically receives a plurality of CIDs (Connection IDs) and transmits each measurement message to the same UL resource by using a MIMO scheme. The present invention relates to a terminal emulator capable of acting as a plurality of emulators by receiving a message and a base station performance measuring method using the same.

To date, wireless access to the Internet is largely based on a platform such as WAP (Wireless Application Protocol) or WIPI (Wireless Internet Platform for Interoperability), and access through a mobile telephone network and public wireless LANs and access points. There is a way to approach it. However, in the case of a mobile telephone network, there is a fundamental limitation as a universal means of accessing the Internet due to the limitation of screen size, input interface and billing system based on pay-as-you-go system. In addition, the wireless LAN has a fundamental problem of being vulnerable to mobility, in addition to the local constraint that it can be used only within a few tens of meters around the access point.

In order to overcome this problem, the domestic standard WiBro and 3GPP (long term evolution) and LTE (3GPP) have been proposed as Mobile WiMAX, or a subset thereof, that enables high-speed Internet access even when stationary or moving vehicles with ADSL quality and cost. have.

Meanwhile, Mobile WiMAX and 3GPP LTE support MIMO (Multi Input Multi Output). MIMO refers to an antenna system capable of multiple inputs and outputs. It is a technology that transmits data through several paths by increasing the antenna of the base station and the terminal to two or more, and detects the signal received in each path at the receiving end to reduce interference and lower each transmission speed.

MIMO allows multiple antennas to operate simultaneously, enabling high-speed data exchange. An independent signal is transmitted to the N transmit antennas using the same frequency at the same time. These transmitted signals undergo spatially different fading on the radio channel (a phenomenon in which the intensity of the received radio waves fluctuates in response to changes in the medium through which the received radio waves pass), resulting in non-correlation between the signals received by each antenna. . By transmitting a different signal for each transmission antenna, more data can be transmitted by the number of transmission antennas (N) than before.

In the mobile communication terminal, power supply is limited and power consumption is greater than that of a wireless transmission part. Therefore, in consideration of this, a specification that assumes that the number of transmitting antennas is smaller than the number of receiving antennas has been approved or proposed.

Mobile WiMAX, or IEEE 802.16e, employs three standardization techniques: STTD, spatial multiplexing, and cooperative spatial multiplexing, assuming up to two transmit antennas on the uplink. Dual cooperative spatial multiplexing is a technique of transmitting data simultaneously by receiving the same frequency resource when two terminals each have one transmit antenna. In addition, even when two terminals each have two transmit antennas, only pilots are sent by code multiplexing, and each terminal can send two different data streams.

Meanwhile, 3GPP Long Term Evolution (LTE) is currently discussing open loop multiple transmit / receive antenna technology. The open loop multiple transmit / receive antenna technique of IEEE 802.16e and the open loop multiple transmit / receive antenna technique of IEEE 802.20 when the number of antennas are 2 and 4 are also under consideration in 3GPP LTE. In addition, in order to obtain spatial diversity, a cyclic delay diversity technique has been discussed as a diversity technique that can be more simply implemented in addition to a block code-based space-time (or) encoding technique. In addition, a transmission scheme in which a space-time (or frequency-space) block coding technique and a cyclic delay diversity technique are combined is also discussed.

 1 is a schematic diagram schematically illustrating a system for measuring a packet error rate of a base station supporting conventional cooperative spatial multiplexing. As shown, in order to measure the packet error rate of a base station supporting cooperative spatial multiplexing, two terminal emulators 1 are conventionally used to transmit a test message through the same UL resource from each terminal emulator 1. 100) and a response message transmitted from the base station 100 to receive a packet error rate.

Here, the terminal emulator 1 requests a network entry from the base station 100 to establish a connection with the base station 100 to replace the actual terminal, and sends a test signal to the base station 100 to respond to the corresponding response. It refers to a portable Internet measuring instrument having a function of receiving a signal, analyzing the same, and measuring the performance of the base station.

However, this method is disadvantageous because it requires a lot of expensive terminal emulator.

The present invention was devised to solve this problem. The object of the present invention is to physically measure the performance of a base station by receiving a plurality of CIDs from a base station, thereby realizing the functions of the plurality of terminal emulators with one terminal emulator. To provide a terminal emulator and a base station performance measurement method using the same.

According to the present invention described above, the terminal emulator according to the present invention generates a test message including a plurality of CIDs (Connection IDs) allocated from the base station, and transmits a test message to the base station through the same uplink (UL) resource. Measure the performance of the base station by receiving a response message corresponding to the, and provide this, but generates a test message containing different CIDs assigned through the network entry from the base station to the base station through the uplink (UL) An RF processor for outputting a signal processing unit, a test message output from the signal processing unit to the base station, and receiving a response message transmitted from the base station through a down link (DL), and driving the signal processing unit and the RF processing unit. Control and the test message output from the signal processor and the RF processor Comparing the response message received from the a control unit for outputting to measure the performance of the base station.

According to a characteristic aspect of the present invention, the signal processing unit of the terminal emulator according to the present invention generates a first test message including one CID according to a control signal of a controller, in order to send a test message having a plurality of CIDs, A first test message generation unit for outputting the generated first test message to the RF processing unit through an up link (UL), a second test message including one CID according to a control signal of the control unit, And a second test message generator for outputting the generated second test message to the RF processor through an up link (UL).

In addition, the method for measuring base station performance according to the present invention comprises the steps of: (a) generating a test message including a plurality of CIDs allocated from the base station through a network entry to the base station, and downlinking each generated test message ( (B) allocating the same UL resources according to the uplink (UL) rules included in the downlink (DL: DL) and transmitting the same UL resources to the base station through the uplink (UL); (C) receiving a response message corresponding to the test message via a down link (DL), and comparing the received response message with the test message to calculate the performance of the base station.

According to a characteristic aspect of the present invention, a method for measuring base station performance according to the present invention generates a first test message including one CID among different CIDs allocated from a base station, and assigns a sequence number to the generated first test message. And (a2) generating a second test message including another CID among different CIDs allocated from the base station, and assigning a sequence number to the generated second test message.

Accordingly, the terminal emulator and the base station performance measurement method using the same according to the present invention physically one terminal emulator is assigned a different CID to the base station and transmits a test message with each CID to the base station through the same UL resources. The performance of the base station can be measured by receiving a response message corresponding to the transmitted test message.

In the terminal emulator and the method for measuring base station performance using the same, a plurality of CIDs are allocated to a base station, a test message including each CID is transmitted to the base station through the same UL resource, and a response message corresponding thereto is received. By measuring the performance of the base station, it is possible to measure the performance of the base station supporting the cooperative MIMO using one terminal emulator physically without the need for multiple terminals.

In addition, the terminal emulator and the method for measuring the performance of the base station using the same according to the present invention have the advantage that the cell processing capacity can be improved from the standpoint of the base station because each message including a plurality of CIDs share one UL resource.

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter, the present invention will be described in detail to enable those skilled in the art to easily understand and reproduce the present invention.

2 is a schematic diagram schematically showing a network configuration of a general Mobile WiMAX. As shown, the basic network configuration of the portable Internet system includes a portable Internet Station (PSS), a Radio Access Station (RAS), and an Access Control Router (ACR), which are referred to as terminals. Is done.

In the above configuration, the terminal (PSS) performs a wireless Internet access, IP-based service access, IP mobility, terminal / user authentication and security, multicast service reception and interworking with other networks. On the other hand, the base station (RAS) performs wireless Internet access, radio resource management and control, mobility (handover) support, authentication and security, QoS, downlink multicast, billing, statistical information generation and notification functions. Finally, the control station (ACR) is responsible for IP routing and mobility management, authentication and security, QoS provisioning, IP multicast, providing billing services for billing servers, mobility control between base stations (RAS) within the control station (ACR), resource management, and Perform control functions.

3 is a block diagram schematically illustrating a terminal emulator according to an exemplary embodiment of the present invention. As shown, according to an exemplary aspect of the present invention, the terminal emulator 200 generates a test message having a plurality of connection IDs (CIDs) and transmits the test message to the base station 100 through the same UL resource.

Accordingly, the terminal emulator 200 generates a test message including a plurality of CIDs allocated from the base station 100 through a plurality of network entries and outputs a test message to the base station 100 through an uplink (UL). The processor 210 and the RF processor which transmits a test message output from the signal processor 210 to the base station 100 and receives a response message transmitted from the base station 100 through a down link (DL). The controller 220 controls the driving of the signal processor 210 and the RF processor 220, and compares the test message output from the signal processor 210 with the response message received through the RF processor 220 to compare the test message with the base station 100. The control unit 230 to calculate and output the performance of the).

Additionally, the terminal emulator 200 according to the present invention includes an input unit 240 for receiving a user's operation command or measurement parameter, and a display unit 250 for displaying a packet error rate calculated by the controller 230 to the user. And a memory 260 for storing and managing the packet error rate calculated by the controller 230.

The signal processor 210 may be implemented, for example, as a Field Programmable Gate Array (FPGA) or a Digital Signal Processor (DSP), and the plurality of CIDs allocated from the base station 100 according to a control signal of the controller 230. Generates a test message to be sent to the base station 100 through the RF processing unit 220. In this case, the test message is generated by attaching the MAC header and the CRC in the MAC layer of the mobile Internet communication.

In the present specification, the present invention will be described through an embodiment in which one terminal emulator 200 is allocated with two CIDs and operates like two terminal emulators 200.

Accordingly, the signal processor 210 of the terminal emulator 200 according to the present invention physically includes a plurality of test message generators so that one terminal emulator 200 operates as a plurality of terminal emulators 200 and is supported by MIMO. Simultaneously transmits a test message to the base station 100 through a transmitting antenna. Accordingly, the signal processor 210 according to the present invention generates a first test message including one CID according to the control signal of the controller 230 and uplinks the generated first test message. Generates a second test message including one CID according to the control signal of the first test message generating unit 211 and the control unit 230, and outputs to the RF processing unit 220 through the second test message It includes a second test message generator 212 for outputting to the RF processing unit 220 through the uplink (UL: Up Link). In addition, the signal processor 210 of the terminal emulator 200 according to the present invention may have two or more test message generators according to its use.

As described above, the first test message generator 211 and the second test message generator 212 are implemented as an FPGA or a DSP, and include an example of a test message including each of two CIDs allocated from the base station 100. For example, a PING-REQ of an IP terminal is generated and transmitted to the base station 100 through an uplink (UL).

Meanwhile, Mobile WiMAX or 3GPP LTE supporting cooperative MIMO is provided from the base station 100 at the time of network entry, for example, in case of Mobile WiMAX, UL MAP of downlink (DL) or uplink control of 3GPP LTE. A test message generated through a physical uplink control channel (PUCCH), that is, a PING-REQ of an IP terminal is transmitted to the base station 100 through the same UL resource.

Accordingly, the first and second test messages PING-REQ generated by the first test message generator 211 and the second test message generator 212 are transmitted to the base station 100 through the RF processor 220. do.

In order to transmit data simultaneously by receiving the same UL resource with a test message having different CIDs, and to allow the base station 100 to distinguish the channel estimation pilot for each antenna, a null subcarrier is used to prevent collision between pilots between antennas. do.

4 is a schematic diagram illustrating a pilot allocation method for two transmit / receive antennas in uplink defined by Mobile WiMAX, an example of the present invention. As shown, by differently assigning null subcarriers to antenna 0 and antenna 1, the base station 100 can receive the first and second test messages by antenna.

Accordingly, the base station 100 classifies each test message through the CIDs included in the first and second test messages, and transmits first and second response messages corresponding thereto.

According to a characteristic aspect of the present invention, the performance measurement of the base station 100 according to the present invention is a ratio of the number of packets received by the terminal emulator 200 to the base station 100, that is, the packet error rate (PER). Can be.

Accordingly, the first and second test message generators 211 and 212 according to the present invention generate the first and second test messages including the sequence number when generating the first and second test messages, respectively, and increase the sequence number by one. .

The sequence number checks the sequence number of the PING-RSP received from the base station 100 and allows the controller 230 to calculate the ratio of the number of received packets to the number of received packets, that is, the packet error rate. In addition, the base station 100 may also calculate the PER at the base station 100 by checking only the sequence number of the PING-REQ transmitted from the terminal emulator 200.

The RF processing unit 220 modulates the test message generated by the signal processing unit 210 to the RF, and transmits the modulated signal to the base station 100 through the uplink (UL), and from the base station 100. RF demodulated and outputs the demodulated response message.

The RF processor 220 receives the first test message generated by the first test message generator 211 and outputs the first test message to the base station 100, and the first response corresponding to the first test message from the base station 100. Receives a second test message generated by the first antenna unit 221 and the second test message generation unit 212 to receive the message and output to the control unit 230 and outputs to the base station 100, the base station ( And a second antenna unit 222 which receives the second response message corresponding to the second test message from the 100 and outputs it to the control unit 230.

In addition, the first and second antenna units 221 and 222 may include a D / A converter for converting a test message output from the signal processor 210, that is, a digital signal into an analog signal corresponding thereto, and the base station 100. A / D converter for converting an analog signal into a digital signal may be included.

The D / A converter of the first antenna unit 221 modulates the digital first test message generated by the first test message generator 211 into an analog signal and converts the modulated signal into a control signal of the controller 230. Accordingly, in the case of Mobile WiMAX, UL MAP of downlink (DL) is used, and in the case of 3GPP LTE, the same UL resource is used by referring to uplink (UL) regulation defined in the uplink control channel (PUCCH). To the base station 100. In addition, the A / D converter of the first antenna unit 221 receives a first response message corresponding to the first test message transmitted from the base station 100, demodulates the digital signal, and controls the demodulated signal to the control unit 230. Will output

The D / A converter of the second antenna unit 222 modulates the digital second test message generated by the second test message generator 212 into an analog signal and converts the modulated signal into a control signal of the controller 230. Accordingly, in the case of Mobile WiMAX, UL MAP of downlink (DL) is used, and in the case of 3GPP LTE, the same UL resource is used by referring to uplink (UL) regulation defined in uplink control channel (PUCCH). To the base station 100. In addition, the A / D converter of the second antenna unit 222 receives a second response message corresponding to the second test message transmitted from the base station 100 and demodulates the digital signal, and controls the demodulated signal to the controller 230. Will output

The first and second test messages output from the first and second antenna units 221 and 222, respectively, are mixed on the air between the terminal emulator 200 and the base station 100 because they use the same UL resources. To be transmitted to the base station 100.

According to another aspect of the present invention, the RF processing unit 220 according to the present invention may mix and transmit the first and second test messages having a plurality of CIDs to the base station 100 through one antenna unit.

Accordingly, the RF processor 220 transitions the first and second test messages having different CIDs output by the first test message generator 211 and the second test message generator 212 to the same frequency and outputs the same. The message mixing unit (not shown) and the first and second test messages mixed by the mixing unit (not shown) are transmitted to the base station 100, and the first and second response messages are output from the base station 100. It includes an antenna unit for receiving and outputting.

In addition, the RF processor 220 according to another aspect of the present invention may also output the first and second test messages, that is, the digital signals corresponding to the first and second test message generators 211 and 212. A D / A converter for converting the signal and an A / D converter for converting an analog message into a digital signal, that is, a response message received from the base station 100 may be included.

The first and second test messages output from the first and second test message generators 211 and 212 are mixed by the message mixing unit (not shown) and output through the same UL resource, and the message mixing unit (not shown). ) And the first and second test messages are mixed with the D / A converter and output to the base station 100.

On the contrary, upon receiving the first and second response messages corresponding to the first and second test messages received by the antenna unit from the base station 100 and individually received, the A / D conversion unit receives the corresponding first and second responses. Each message is demodulated into a digital signal, and the demodulated signal is output to the controller 230.

The controller 230 controls the entire device of the terminal emulator 200, and may be implemented as a microcomputer including a microprocessor for implementing a microprocessor for calculation and a peripheral device thereof in one integrated circuit. For example, the controller 230 may receive two CIDs from the base station 100 through two network entries with the base station 100 and generate a test message PING-REQ including each CID. The control signal is output to the second test message generators 211 and 212, and a response message (PING-RSP) corresponding to the test message output from the base station 100 is received, for example, a packet of the base station 100. The performance of the base station 100 such as an error rate (PER) is measured and provided.

According to a characteristic aspect of the present invention, the controller 230 according to the present invention includes a base station 100 and a sequence number of the first and second test messages generated by the first and second test message generators 211 and 212. A packet error rate (PER) is calculated by comparing the sequence numbers included in the first and second response messages received from.

The controller 230 compares the number of test messages PING-REQ sent to the base station 100 through the uplink with the number of response messages PING-RSP received from the base station 100 through the downlink. The error rate is calculated. In this case, if a CRC error occurs in the test message or the response message, the CRC error message is filtered out of the MAC terminal of the terminal emulator 200, so that the terminal cannot even arrive at the IP terminal, which is considered as a sequence number error. have. Accordingly, the PHY stage checks the sequence number of the received response message (PING-RSP) and calculates the number of filtered messages in the middle, thereby calculating the ratio of the number of received packets to the number of received packets, that is, the packet error rate (PER). Can be calculated.

According to a characteristic aspect of the present invention, the control unit 230 according to the present invention transmits the first and second test messages having different CIDs to the base station 100 using the same UL resources, thereby supporting cooperative MIMO. Performance measurement of the base station 100 is possible.

Accordingly, the control unit 230 is a UL MAP of downlink (DL) for Mobile WiMAX at the time of network entry, and uplink (UL: Uplink) defined by an uplink control channel (PUCCH) for 3GPP LTE. The first and second test messages having different CIDs generated by the first and second test message generators 211 and 212 with reference to the regulations may be output to the base station 100 through the same UL resource. The control signal is output to the second test message generators 211 and 212.

5 is a schematic diagram schematically showing a UL MAP of a downlink of Mobile WiMAX according to an embodiment of the present invention. As shown, the first and second test messages having different CIDs generated by the first and second test message generators 211 and 212 according to the present invention are displayed in color and frequency domain in FIG. 5. That is, it is defined to be allocated to the UL resource region and transmitted to the base station 100 through the uplink. These UL resources are defined in UL MAP of downlink (DL) for Mobile WiMAX, and uplink (UL) rules for uplink control channel (PUCCH) for 3GPP LTE.

In the case of the base station 100 supporting the cooperative MIMO, the terminal emulator 200 performs UL MAP of downlink (DL) for mobile WiMAX at the time of network entry, and uplink control channel (PUCCH) for 3GPP LTE. In the uplink (UL) rule defined in the following, for example, two terminals, that is, the same UL resources are allocated from the terminal emulator 200 having two CIDs to transmit data simultaneously.

Accordingly, as described above, the controller 230 transmits the first and second test messages having different CIDs generated by the first and second test message generators 211 and 212 through the same UL resource. The physical performance of the base station 100 supporting the cooperative MIMO function can be measured through one terminal emulator 200.

Hereinafter, a method of measuring a packet error rate of the base station 100 using the terminal emulator 200 will be described.

6 is a flowchart schematically illustrating a process of measuring a base station packet error rate according to an exemplary embodiment of the present invention. As shown, the method for measuring base station performance according to the present invention comprises the steps of: (a) generating a test message each including a plurality of CIDs allocated from the base station 100 through a network entry to the base station 100; (B) transmitting each test message to the base station 100 through an uplink (UL) by allocating the same UL resource, and downlinking the response message corresponding to the test message from the base station 100. (C) receiving through DL (DL: Down Link), and (d) calculating the performance of the base station 100 by comparing the received response message with the test message.

When the user inputs a driving command for the terminal emulator 200 to measure the performance of the base station 100 supporting the collaborative MIMO, the terminal emulator 200 is assigned, for example, two CIDs through a network entry ( S101). This network entry process includes the following steps for Mobile WiMAX.

a) Scan for the downlink channel and set up synchronization with the base station.

b) Get the Tx parameters from the UCD message.

c) performs a ranging function.

d) negotiate basic provisioning capabilities;

e) Authorize the terminal and exchange keys.

f) register.

g) Set up an IP connection.

h) Set the time of day.

i) transmit operating parameters;

j) Establish a connection.

If a single terminal emulator 200 is assigned a plurality of CIDs through the network entry process, the terminal emulator 200 attempts a plurality of network entries according to the number of terminals to be managed and operated. However, it registers with the base station with different MAC ADDR, and the base station thinks the different MAC ADDR as different independent terminals and repeats the procedure of allocating different CIDs independently. In this case, different CIDs may be regarded as BASIC CIDs, that is, connection identifiers uniquely assigned to each terminal in the WiMAX standard. In addition, a single terminal emulator 200 may be assigned two or more CIDs, because one terminal may request a base station to allocate several CIDs for each QoS. Become a concept. The concept of a plurality of CIDs referred to herein is generally used as a delimiter for distinguishing different terminals, and in some cases, may include a concept as a delimiter of QoS.

That is, one terminal emulator 200 may perform a network entry with different MAC ADDRs to register with a base station as a different terminal and allocate a CID according to the terminal, and thus operate as a different terminal. When UL resources are allocated to two CIDs allocated to two terminals for reception of the UE, the terminal emulator 200 recognizes all of them and acts as if the signals are transmitted from the two terminals. The base station should open the UL resource with each CID assigned to different terminals for UL Collaborative Spatial Multiplexing (CSM).

The controller 230 outputs a control signal to the signal processor 210 to generate a test message for measuring the performance of the base station including each of the two assigned CIDs. The signal processor 210 generates test messages having respective CIDs through the first and second test message generators 211 and 212 according to the control signal of the controller 230 (S103). Each test message generated at this time is assigned a sequence number.

The test message generated by assigning each sequence number is defined in UL MAP of down link (DL) for Mobile WiMAX provided from the base station 100 and in uplink control channel (PUCCH) for 3GPP LTE. The UL is transmitted to the base station 100 through the uplink with reference to an uplink (UL) rule (S105).

As described above, in the case of the base station 100 supporting the cooperative MIMO, two test messages provided to the terminal, that is, PING-REQ of the IP terminal are transmitted to the base station 100 through the same UL resource. Accordingly, the first and second test messages generated by the first test message generator 211 and the second test message generator 212, that is, the PING-REQ are transmitted to the base station 100 through the RF processor 220. do.

At this time, each of the test messages having different CIDs are allocated the same UL resource and simultaneously transmit data, and the base station 100 distinguishes the channel estimation pilots by antenna using null subcarriers to prevent antenna collisions between the antennas. .

When the test message is transmitted from the terminal emulator 200 through the uplink, the base station 100 transmits a response message corresponding to the test message, that is, the PING-RSP to the terminal emulator 200 through the downlink, and the terminal emulator. The RF processing unit 220 of 200 receives and demodulates the response message and outputs the demodulated message to the control unit 230 (S107).

The controller 230 compares the sequence numbers of the first and second test messages given when the test message is generated with the sequence numbers included in the first and second response messages received from the base station 100 to determine the packet error rate PER. It calculates (S109).

More specifically, the control unit 230 is the number of test messages (PING-REQ) sent to the base station 100 through the uplink and the number of response messages (PING-RSP) received from the base station 100 through the downlink The packet error rate is calculated by comparing.

In this case, if a CRC error occurs in the test message or the response message, the CRC error message is filtered out of the MAC terminal of the terminal emulator 200, so that the terminal cannot even arrive at the IP terminal, which is considered as a sequence number error. have. Accordingly, the PHY stage checks the sequence number of the received response message (PING-RSP) to calculate the number of filtered messages in the middle, thereby calculating the ratio of the number of received packets to the number of received packets, that is, the packet error rate (PER). It may be (S111). The packet error rate PER calculated by the controller 230 through the above-described method is provided to the user through display means which may be additionally provided.

1 is a schematic diagram schematically illustrating a system for measuring a packet error rate of a base station supporting conventional cooperative spatial multiplexing.

2 is a schematic diagram schematically showing a network configuration of a general Mobile WiMAX.

3 is a block diagram schematically illustrating a terminal emulator according to an exemplary embodiment of the present invention.

4 is a schematic diagram illustrating a pilot allocation method for two transmit / receive antennas in uplink defined by Mobile WiMAX, an example of the present invention.

5 is a schematic diagram schematically showing a UL MAP of a downlink of Mobile WiMAX according to an embodiment of the present invention.

6 is a flowchart schematically illustrating a process of measuring a base station PER according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

1, 200. Terminal emulator 100. Base station

210. Signal processor 211. First test message generator

212. Second Test Message Generator 220. RF Processor

221. First antenna unit 222. Second antenna unit

230. Control unit 240. Input unit

250. Display unit 260. Memory

Claims (14)

Manages a plurality of CIDs (Connection IDs) allocated from the base station, generates a test message including each CID, sends the same to the base station through the same uplink (UL) resource, and receives a response message corresponding to the test message. A terminal emulator that measures the performance of the base station and provides the measurement results, The terminal emulator generates a test message including different CIDs allocated through the network entry from the base station and outputs the test message to the base station through the UL; And a controller for comparing a test message output from the signal processor and a received response message to measure the performance of the base station. The device of claim 1, wherein the terminal emulator is: An RF processor for transmitting a test message output from the signal processor to the base station and receiving a response message transmitted from the base station through a down link (DL); The control unit emulator for controlling the driving of the signal processing unit and the RF processing unit. The method of claim 2, wherein the signal processing unit: A first test message generation unit generating a first test message including one CID according to a control signal of the controller and outputting the generated first test message to the RF processor through an up link (UL); Wow; A second test message generation unit generating a second test message including one CID according to a control signal of the controller and outputting the generated second test message to the RF processor through an uplink (UL); Terminal emulator comprising a. The method of claim 3, wherein the first and second test message generators include: And generating a sequence number in the first and second test messages, respectively. The method according to claim 4, Terminal emulator, characterized in that the first and second test message generator is implemented in the FPGA or DSP. The method of claim 4, wherein the control unit: A packet error rate (PER) is compared by comparing the sequence numbers of the first and second test messages generated by the first and second test message generators with the sequence numbers included in the first and second response messages received from the base station. The terminal emulator characterized in that for outputting. The method of claim 6, wherein the control unit: The first and second test messages are allocated to the same UL resources according to UL Uplink (UL) rules of the downlink (DL) of the downlink (DL) transmitted from the base station supporting Mobile WiMAX and output to the base station. And a control signal output to the first and second test message generators. The method of claim 6, wherein the control unit: The first and second test messages are allocated to the same UL resources according to uplink (UL) rules of an uplink control channel of 3rd Generation Partnership Project (3GPP) long term evolution (LTE) and output to the base station. And a control signal output to the first and second test message generators. The method according to claim 3, wherein the RF processing unit: A first antenna unit receiving the first test message generated by the first test message generator and outputting the first test message to the base station, receiving a first response message corresponding to the first test message from the base station, and outputting the first test message to the controller; And a second antenna unit receiving the second test message generated by the second test message generator and outputting the second test message to the base station, receiving a second response message corresponding to the second test message from the base station, and outputting the second test message to the controller. Terminal emulator, characterized in that. The method according to claim 3, wherein the RF processing unit: A message mixing unit for translating and outputting first and second test messages having different CIDs output by the first test message generator and the second test message generator to the same frequency; And an antenna unit for transmitting the first and second test messages mixed by the mixing unit to the base station, and receiving and outputting the first and second response messages output from the base station. (A) respectively generating test messages including different CIDs assigned from the base station through the network entry to the base station; (B) transmitting each generated test message to a base station through an uplink (UL) by allocating the same UL resource; (C) receiving a response message corresponding to the test message from the base station through a down link (DL); And (d) comparing the received response message with the test message to calculate the performance of the base station. The method of claim 11, wherein step (a) comprises: (A1) generating a first test message including one CID among different CIDs allocated from the base station, and assigning a sequence number to the generated first test message; And (a2) generating a second test message including another CID among different CIDs allocated from the base station and assigning a sequence number to the generated second test message. Way. The method of claim 12, wherein step (b) comprises: And transmitting the first test message generated in step (a1) and the second test message generated in step (a2) through different RF transmitters. The method of claim 12, wherein step (d) comprises: And calculating a packet error rate (PER) by comparing the sequence number of the test message sent to the base station and the sequence number included in the response message received from the base station.

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