JP5139550B2 - Mobile communication terminal test system, base station simulation apparatus, and delay time measurement method - Google Patents

Description

  The present invention relates to a technique for measuring a delay time between a mobile communication terminal and a base station, and more particularly to a technique for measuring a delay time generated in the mobile communication terminal.

  When communication is performed between a base station and a mobile communication terminal, a delay occurs until a signal (for example, an audio signal) input to one device is output from the other device. This is because it takes time to process signals and data in functional blocks (components) constituting each device. A manufacturer of a mobile communication terminal needs to notify a telecommunications carrier of a delay time generated in the manufactured mobile communication terminal, and measures the delay time.

  Conventionally, it was possible to measure the delay time for each functional block constituting the mobile communication terminal and theoretically calculate the delay time of the mobile communication terminal based on these measured values.

  On the other hand, in recent years, each mobile communication terminal has been manufactured by combining functional blocks and modularized parts. These modularized parts are made into black boxes, making it difficult for manufacturers to calculate the theoretical value of the delay time of mobile communication terminals.

  Therefore, a method of measuring the delay time of the manufactured mobile communication terminal itself has been used. In such a case, the mobile communication terminal test system is configured by connecting the mobile communication terminal to the base station simulator, and the delay time of this system is measured. Specifically, a test signal is transmitted from the base station simulator to the mobile communication terminal, and a delay time between this test signal and the signal received by the mobile communication terminal is measured. Since the measured delay time includes the delay time in the base station simulator, the delay time of the mobile communication terminal can be calculated by subtracting this.

  On the other hand, such a base station simulator is desired to be configured to test a plurality of mobile communication terminals having different communication methods. By the way, if the communication method is different, the data processing unit (for example, frame length or slot length) differs depending on the communication method. Therefore, the base station simulation device converts the data of the input signal into data for each processing unit of the selected communication method. Specifically, the base station simulator first stores the data of the input signal temporarily in a storage unit such as a memory. The base station simulator reads out the data stored in the storage unit for each processing unit corresponding to the communication method in the order of storage (that is, FIFO: First In First Out). As a result, the data processing unit is converted from the processing unit corresponding to the input signal to the processing unit corresponding to the communication method. The same applies to the reverse case, that is, when the signal corresponding to the communication method is received from the mobile communication terminal and the signal is output from the base station simulator. In this case, the processing unit corresponding to the communication method is converted to the processing unit corresponding to the signal output from the base station simulator via the storage unit.

  However, in the conventional base station simulation apparatus, the processing time required for the conversion of the data processing unit cannot be uniquely determined. This is because the start of writing data to the storage unit and the start of reading data stored in the storage unit operate asynchronously, resulting in variations in the period from the input of data to the output. It is. For this reason, it is difficult for the conventional base station simulator to uniquely identify the delay time, and the delay time of the mobile communication terminal can be accurately calculated based on the delay time of the mobile communication terminal test system. It was difficult.

JP 10-42343 A

  An object of the present invention is to make it possible to accurately calculate the delay time of a mobile communication terminal by adopting a configuration capable of uniquely specifying the delay time of a base station simulator.

In order to achieve the above object, the invention described in claim 1 includes a test signal generation unit (1) for generating an analog first test signal, and a wireless communication system in which the first test signal is designated. A base station simulator (2) that converts the signal into a signal to be output to the terminal under test, an analog second test signal that is output from the terminal under test upon receiving the radio signal, and the first test signal; And a measuring unit (4) for measuring a time difference between the first test signal and the second test signal, and a mobile unit for testing a plurality of types of the terminals under test having different communication methods. In the body communication terminal test system, the base station simulation device performs an A / D conversion on the first test signal and outputs it as a digital signal; a storage unit (213); The digital signal is encoded based on a predetermined conversion method. A series of digital data, and an encoding processing unit (212) that sequentially writes the digital data to the storage unit for each first unit; and the digital data for each second unit in the order of storage. A frame generation unit (214) that reads out from the storage unit and processes the read digital data based on the designated communication method to generate frame data; and D that converts the frame data into an analog baseband signal An A / A converter (215), a frequency converter (216) for frequency-converting the baseband signal in accordance with the designated communication method and outputting it to the mobile communication terminal to be tested, and the encoding processor The start of writing the series of digital data to the storage unit, and the frame generation unit from the storage unit to the series of digital data. A timing control unit (217) that synchronizes with the timing to start reading data, and each of the delay times until the base station simulator receives the first test signal and outputs the radio signal A mobile communication terminal test system characterized in that the communication system is kept constant.
According to a second aspect of the present invention, there is provided a test signal generator (1) for generating an analog third test signal and a radio signal output from a terminal under test that has received the third test signal. Receiving the third test signal and the fourth test signal, the base station simulator (2) that converts the test signal into an analog fourth test signal based on the designated communication method, and outputs the analog test signal. A mobile communication terminal test system for testing a plurality of types of terminals under test having different communication methods, and a measurement unit (4) for measuring a time difference between a third test signal and the fourth test signal The base station simulator receives the radio signal, converts the frequency based on the designated communication method, and outputs the baseband signal as a baseband signal, and the baseband signal as A / D conversion and frame data A D / A conversion unit (225), a storage unit (223), and a frame unit that processes the frame data based on the designated communication method to extract a series of digital data, and outputs the digital data to a third unit. A frame analysis unit (224) that sequentially writes to the storage unit every time, and the digital data is read from the storage unit for each fourth unit in the stored order, decoded based on a predetermined conversion method, and converted into a digital signal A decoding processing unit (222) for outputting, a D / A conversion unit (221) for converting the digital signal into the fourth test signal, and the frame analysis unit for the series of digital data to the storage unit. Timing to synchronize the timing for starting writing and the timing for the decoding processing unit to start reading the series of digital data from the storage unit A delay time until the base station simulator receives the radio signal and outputs the fourth test signal in each communication system. This is a body communication terminal test system.
According to a third aspect of the present invention, there is provided an A / D converter (211) that receives an analog test signal, A / D converts the test signal and outputs the signal as a digital signal, and a storage unit (213). The digital signal is encoded based on a predetermined conversion method to generate digital data, and the digital data is sequentially written to the storage unit for each first unit; and an encoding processing unit (212), A frame generation unit (214) that reads out the digital data for each second unit in the stored order and processes the read digital data based on a designated communication method to generate frame data; and the frame A D / A converter (215) for converting data into an analog baseband signal, and subjecting the baseband signal to frequency conversion according to the specified communication method A frequency conversion unit (216) that outputs to a mobile communication terminal; a timing at which the encoding processing unit starts writing the series of digital data to the storage unit; and a frame generation unit that includes the storage unit And a timing control unit (217) that synchronizes the timing to start reading the series of digital data.
According to a fourth aspect of the present invention, there is provided a frequency converter (226) that receives an analog radio signal from a mobile communication terminal to be tested, converts the frequency based on a designated communication method, and outputs the result as a baseband signal. ), A D / A converter (225) for A / D converting the baseband signal and outputting it as frame data, a storage unit (223), and processing based on the designated communication method from the frame data The frame analysis unit (224) that sequentially extracts the digital data and sequentially writes the digital data to the storage unit for each third unit; and the digital data from the storage unit for each fourth unit in the stored order. Decoding processing unit (222) that reads out, decodes based on a predetermined conversion method and outputs as a digital signal, and converts the digital signal into an analog test signal The D / A conversion unit (221), the timing at which the frame analysis unit starts writing the series of digital data to the storage unit, and the decoding processing unit from the storage unit to the series of digital data And a timing control unit (227) that synchronizes with the timing to start reading of the base station.
According to a fifth aspect of the present invention, there is provided a test signal generating step for generating an analog first test signal, and an A / D conversion step for A / D converting the first test signal and outputting it as a digital signal. An encoding processing step for encoding the digital signal based on a predetermined conversion method to generate digital data, a writing step for sequentially writing the digital data to a storage unit for each first unit, and the writing step In synchronization with the digital data, a reading step of reading out the digital data from the storage unit for each second unit in the stored order, and processing the read digital data based on a designated communication method to obtain frame data A frame generation step for generating, a D / A conversion step for converting the frame data into an analog baseband signal, and A frequency conversion step of generating a radio signal by frequency-converting a baseband signal in accordance with the designated communication method, and outputting the radio signal to a mobile communication terminal to be tested; and receiving the radio signal and the terminal under test Measuring a time difference between the first test signal and the second test signal in response to the analog second test signal output from the first test signal and the first test signal; It is the delay time measuring method characterized by having provided.
According to a sixth aspect of the present invention, a test signal generating step for generating an analog third test signal and a radio signal output from the terminal under test that has received the third test signal are specified. A frequency conversion step of converting the frequency based on the determined communication method and outputting as a baseband signal, a D / A conversion step of A / D converting the baseband signal and outputting as frame data, and the frame data as the designation A frame analysis step of extracting digital data by processing based on the communication method, a writing step of sequentially writing the digital data to a storage unit for each third unit, and the digital data in synchronization with the writing step, A reading step of reading from the storage unit for each fourth unit in the stored order; and the read digital data Are decoded based on a predetermined conversion method and output as a digital signal, a D / A conversion step for converting the digital signal into the fourth test signal, the third test signal, and the third test signal And a measurement step of measuring a time difference between the third test signal and the fourth test signal in response to the four test signals.

  The technology according to the present invention starts reading digital data from the storage unit in synchronization with the start of writing of the digital data to the storage unit, for example, when attention is paid at the time of transmission. The frame data is generated. Thereby, the delay time until the base station simulator receives the first test signal and outputs the radio signal is kept constant at least for each communication method. This is the same at the time of reception, and the delay time until receiving the radio signal and outputting the fourth test signal is kept constant. Therefore, by measuring the delay time of the mobile communication terminal test system, it is possible to accurately calculate the delay time of the mobile communication terminal based on the delay time of this system and the delay time of the base station simulator. Become.

1 is a block diagram of a mobile communication terminal test system according to a first embodiment. It is a block diagram of the transmission part of a base station simulation apparatus. It is the flowchart which showed a series of processes of the mobile communication terminal test system which concerns on 1st Embodiment. It is a block diagram of the mobile communication terminal test system which concerns on 2nd Embodiment. It is a block diagram of the receiving part of a base station simulation apparatus. It is the flowchart which showed a series of processes of the mobile communication terminal test system which concerns on 2nd Embodiment.

  The measurement of the delay time of the mobile communication terminal includes “measurement at reception” and “measurement at transmission”. In “measurement at the time of reception”, a delay time when the mobile communication terminal receives a signal from the base station is measured. In “measurement at the time of transmission”, a delay time when the mobile communication terminal transmits a signal to the base station is measured. The mobile communication terminal test apparatus according to the present invention is configured to test a plurality of mobile communication terminals having different communication methods. This communication system includes W-CDMA (Wideband-Division Multiple Access), GSM, TD-SCDMA (Time Division Synchronous Code Division Multiple Access), and the like. In the following, the mobile communication terminal test system according to the present invention will be described by taking as an example a case where audio signals are transmitted and received between the base station and the mobile communication terminal. First, the configuration and operation of a mobile communication terminal test system according to “measurement during reception” will be described as a first embodiment. The configuration and operation of the mobile communication terminal test system related to “measurement at the time of transmission” will be described later as a second embodiment.

(First embodiment)
The configuration of the mobile communication terminal test system according to the first embodiment will be described with reference to FIG. As shown in FIG. 1, the mobile communication terminal test system according to the present embodiment includes a test signal generation unit 1, a base station simulation device 2, and a measurement unit 4, and tests the terminal under test 3. It is supposed to be. The base station simulation apparatus 2 includes a transmission unit 21 and a reception unit 22, and the transmission unit 21 is used in the present embodiment (that is, “measurement during reception”). The receiving unit 22 is used in the second embodiment (that is, “measurement during transmission”).

  The test signal generator 1 generates a test analog audio signal AF1. The test signal generation unit 1 outputs the generated audio signal AF1 to the transmission unit 21 and the measurement unit 4. The transmission unit 21 and the measurement unit 4 will be described later. Note that the audio signal AF1 corresponds to a “first test signal”.

  The transmitter 21 receives the audio signal AF1 from the test signal generator 1. The transmission unit 21 converts the audio signal AF1 into digital data, performs encoding and modulation on the basis of a predetermined communication method specified as a measurement condition, and converts it into an analog carrier RF. Details of the operation of the transmitter 21 will be described with reference to FIG. FIG. 2 is a block diagram of the transmission unit 21.

  As illustrated in FIG. 2, the transmission unit 21 includes an A / D conversion unit 211, an encoding processing unit 212, a storage unit 213, a frame generation unit 214, a D / A conversion unit 215, and a frequency conversion unit 216. And a timing control unit 217.

  The audio signal AF1 output from the test signal generator 1 is input to the A / D converter 211. The A / D conversion unit 211 performs A / D conversion on the audio signal AF1 and outputs the digital signal Dx to the encoding processing unit 212.

  The encoding processing unit 212 receives the digital signal Dx from the A / D conversion unit 211. The encoding processing unit 212 converts data for a predetermined unit U1 into one block, and converts the digital signal Dx into digital data Dy for each block based on a predetermined codec (that is, conversion method: audio data compression processing in this case). To do. This codec is, for example, a GSM-AMR audio codec. Here, the predetermined unit U1 indicates the codec frame length (for 20 ms).

  Upon receiving an instruction from the timing control unit 217, the encoding processing unit 212 starts writing the digital data Dy to the storage unit 213. At this time, the encoding processing unit 212 writes the digital data Dy into the storage unit 213 for each block. The timing control unit 217 will be described later. The unit U1 corresponds to the “first unit”.

  The storage unit 213 temporarily stores the digital data Dy (that is, a buffer). The storage unit 213 is configured as a FIFO. The digital data Dy stored in the storage unit 213 is read by the frame generation unit 214 in the order of writing.

  In response to the instruction from the timing control unit 217, the frame generation unit 214 starts reading the digital data Dy stored in the storage unit 213. At this time, the frame generation unit 214 reads out the digital data Dy for each block with the data of the predetermined unit U2 as one block in the order stored in the storage unit 213. Note that the data amount for one block (that is, the unit U2) is set in advance based on the frame length of a communication method designated in advance (hereinafter referred to as “predetermined communication method”). For example, when W-CDMA is specified as the communication method, the frame generation unit 214 processes data for two frames (20 ms) as one block based on the frame length (10 ms). When GSM is designated as the communication method, the frame generation unit 214 processes data for four frames (18.48 ms) as one block based on the frame length (4.62 ms). The unit U2 corresponds to a “second unit”.

  Note that due to the difference in data amount (unit U2) for one block according to the communication method, there may be a difference in the timing at which the head of the data for each block is processed between the communication methods. In that case, the frame generation unit 214 synchronizes the head data of a predetermined block at a predetermined timing (for example, every 60 ms) by inserting empty data at a predetermined timing according to the communication method. Let For example, when GSM is designated, the frame generation unit 214 inserts empty data for one frame every time data for three blocks is processed. By doing so, the processing timing of data for three blocks is synchronized with the processing timing every 60 ms. In the case of W-CDMA, since one block corresponds to 20 ms of data, the processing of data of 3 blocks is synchronized with the processing timing every 60 ms. Therefore, in the case of W-CDMA, the frame generation unit 214 does not insert empty data.

  The frame generation unit 214 modulates the digital data Dy read for each block based on a modulation method (for example, orthogonal modulation) corresponding to a predetermined communication method, and has a frame structure corresponding to the communication method Data Dz is generated. The frame generation unit 214 outputs the frame data Dz to the D / A conversion unit 215. The frame data Dz is a digital baseband signal.

  The timing control unit 217 controls the timing at which the encoding processing unit 212 starts writing the digital data Dy to the storage unit 213 and the timing at which the frame generation unit 214 starts reading the digital data Dy from the storage unit 213. To do. At this time, the timing control unit 217 synchronizes the timing at which writing to the storage unit 213 is started and the timing at which reading from the storage unit 213 is started. Note that the timing at which reading from the storage unit 213 is started may be at the same time as or later than the timing at which writing to the storage unit 213 is started. Further, the timing control unit 217 may be included in one of the configurations of the encoding processing unit 212 and the frame generation unit 214, and may be operated so as to control the timing at which the other configuration starts processing based on an instruction of the configuration. Good.

  When the D / A conversion unit 215 receives the frame data Dz from the frame generation unit 214, the D / A conversion unit 215 performs D / A conversion of the received frame data Dz into an analog signal Ax. The D / A converter 215 outputs the analog signal Ax to the frequency converter 216. The analog signal Ax is an analog baseband signal.

  When receiving the analog signal Ax from the D / A converter 215, the frequency converter 216 converts the frequency of the received analog signal Ax based on a predetermined communication method. The frequency converting unit 216 transmits the frequency-converted analog signal Ax, that is, the carrier wave RF, to the terminal under test 3. Note that the base station simulator 2 and the terminal under test 3 are connected wirelessly or by wire (propagating the carrier wave RF using a coaxial cable for testing). The terminal under test 3 decodes the carrier wave RF based on the predetermined communication method described above, and outputs it as an audio signal AF2 via an output unit such as a speaker. Note that the audio signal AF2 corresponds to the “second test signal”.

  Reference is now made to FIG. The measurement unit 4 receives the audio signal AF1 from the test signal generation unit 1. The measuring unit 4 receives the audio signal AF2 output from the output unit of the terminal under test 3 via an input unit such as a microphone. The measuring unit 4 compares the waveform of the audio signal AF1 with the waveform of the audio signal AF2, and measures the delay time between the two waveforms. In general, a device that can compare a plurality of analog waveforms, such as an oscilloscope, is used as the measurement unit 4. Alternatively, the delay time may be obtained by performing correlation processing of two waveforms.

  Next, a series of operations of the mobile communication terminal test system according to the present embodiment will be described with reference to FIG. FIG. 3 is a flowchart showing a flow of a series of processes of the mobile communication terminal test system.

(Step S11)
The test signal generator 1 generates a test analog audio signal AF1. The test signal generation unit 1 outputs the generated audio signal AF1 to the transmission unit 21 and the measurement unit 4.

(Step S12)
The audio signal AF1 output from the test signal generator 1 is input to the A / D converter 211. The A / D conversion unit 211 performs A / D conversion on the audio signal AF1 and outputs the digital signal Dx to the encoding processing unit 212.

  The encoding processing unit 212 receives the digital signal Dx from the A / D conversion unit 211. The encoding processing unit 212 converts data for a predetermined unit U1 into one block, and converts the digital signal Dx into digital data Dy for each block based on a predetermined codec (that is, conversion method: audio data compression processing in this case). To do.

(Step S13)
Upon receiving an instruction from the timing control unit 217, the encoding processing unit 212 starts writing the digital data Dy to the storage unit 213. At this time, the encoding processing unit 212 writes the digital data Dy into the storage unit 213 for each block.

(Step S14)
In response to the instruction from the timing control unit 217, the frame generation unit 214 starts reading the digital data Dy stored in the storage unit 213. At this time, the frame generation unit 214 reads out the digital data Dy for each block with the data of the predetermined unit U2 as one block in the order stored in the storage unit 213. At this time, the timing control unit 217 has a timing at which the encoding processing unit 212 starts writing the digital data Dy to the storage unit 213 and a timing at which the frame generation unit 214 starts reading the digital data Dy from the storage unit 213. Synchronize with.

(Step S15)
The frame generation unit 214 modulates the digital data Dy read for each block based on a modulation method (for example, orthogonal modulation) corresponding to a predetermined communication method, and has a frame structure corresponding to the communication method Data Dz is generated. The frame generation unit 214 outputs the frame data Dz to the D / A conversion unit 215.

  When the D / A conversion unit 215 receives the frame data Dz from the frame generation unit 214, the D / A conversion unit 215 performs D / A conversion of the received frame data Dz into an analog signal Ax. The D / A converter 215 outputs the analog signal Ax to the frequency converter 216.

  When receiving the analog signal Ax from the D / A converter 215, the frequency converter 216 converts the frequency of the received analog signal Ax based on a predetermined communication method. The frequency converting unit 216 transmits the frequency-converted analog signal Ax, that is, the carrier wave RF, to the terminal under test 3.

(Step S16)
The terminal under test 3 decodes the carrier wave RF received from the frequency converter 216 based on the above-described predetermined communication method, and outputs it as an audio signal AF2 through an output unit such as a speaker. The measuring unit 4 receives the audio signal AF2 output from the output unit of the terminal under test 3 via an input unit such as a microphone.

(Step S17)
The measurement unit 4 receives the audio signal AF1 from the test signal generation unit 1. The measuring unit 4 compares the waveform of the audio signal AF1 with the waveform of the audio signal AF2, and measures the delay time between the two waveforms.

  As described above, according to the base station simulation device 2 according to the present embodiment, the timing at which the digital data Dy is written into the storage unit 213 and the timing at which the digital data Dy is read out from the storage unit 213 under the control of the timing control unit 217. Are synchronized. Thereby, the delay time until the base station simulation apparatus 2 receives the audio signal AF1 and outputs the carrier wave RF is kept constant at least for each communication method. Therefore, it becomes possible to measure the delay time of the base station simulator 2 in advance. Thereby, the measurement unit 4 calculates the delay time between the audio signal AF1 and the audio signal AF2, and subtracts the delay time of the base station simulator 2 measured in advance from the calculated delay time. It becomes possible to calculate the delay time of the test terminal 3 with high accuracy.

(Second Embodiment)
The configuration of the mobile communication terminal test system according to the second embodiment will be described with reference to FIG. As shown in FIG. 4, the mobile communication terminal test system according to the present embodiment includes a test signal generation unit 1, a base station simulation device 2, and a measurement unit 4, and tests the terminal under test 3. It is supposed to be. The base station simulation apparatus 2 includes a transmission unit 21 and a reception unit 22, and the reception unit 22 is used in the present embodiment (that is, “measurement during transmission”).

  The test signal generator 1 generates a test analog audio signal AF3. The test signal generation unit 1 outputs the generated audio signal AF3 to the terminal under test 3 and the measurement unit 4. The measuring unit 4 will be described later. The terminal under test 3 receives the audio signal AF3 via an input unit such as a microphone. The terminal under test 3 converts the received voice signal AF3 into a carrier wave RF by encoding based on a predetermined communication method, and transmits the carrier wave RF to the receiving unit 22. Note that the audio signal AF3 corresponds to a “third test signal”.

  The receiving unit 22 receives the carrier wave RF from the terminal under test 3. The receiving unit 22 decodes the carrier wave RF based on a predetermined communication method designated as a measurement condition, and converts it into an audio signal AF4. Details of the operation of the receiving unit 22 will be described with reference to FIG. FIG. 5 is a block diagram of the receiving unit 22. Note that the audio signal AF4 corresponds to a “fourth test signal”.

  As illustrated in FIG. 5, the reception unit 22 includes a D / A conversion unit 221, a decoding processing unit 222, a storage unit 223, a frame analysis unit 224, an A / D conversion unit 225, and a frequency conversion unit 226. And a timing control unit 227.

  The carrier wave RF transmitted from the terminal under test 3 is input to the frequency converter 226. The frequency converter 226 converts the frequency of the carrier wave RF based on a predetermined communication method. The frequency converter 226 outputs the frequency-converted carrier wave RF, that is, the analog signal Ax, to the A / D converter 225.

  When the analog signal Ax is received from the frequency converter 226, the A / D converter 225 A / D converts the received analog signal Ax into a digital signal. This digital signal corresponds to frame data Dz having a frame structure based on a predetermined communication method. The A / D conversion unit 225 outputs the frame data Dz to the frame analysis unit 224.

  When the frame analysis unit 224 receives the frame data Dz from the A / D conversion unit 225, the frame analysis unit 224 demodulates the received frame data Dz based on a modulation method according to a predetermined communication method, and extracts the digital data Dy.

  In response to the instruction from the timing control unit 227, the frame analysis unit 224 starts writing the digital data Dy to the storage unit 223. At this time, the frame analysis unit 224 writes the extracted digital data Dy into the storage unit 223 for each block, with data of a predetermined unit U2 as one block. The unit U2 is the same as the unit U2 in the first embodiment, and corresponds to a “third unit”.

  The storage unit 223 temporarily stores the digital data Dy (that is, a buffer). The storage unit 223 is configured as a FIFO. The digital data Dy stored in the storage unit 223 is read out by the decoding processing unit 222 in the order of writing.

  Upon receiving an instruction from the timing control unit 227, the decoding processing unit 222 starts reading the digital data Dy stored in the storage unit 223. At this time, the decoding processing unit 222 reads the digital data Dy for each block, with the data of the predetermined unit U1 as one block in the order stored in the storage unit 223. The unit U1 is the same as the unit U1 in the first embodiment, and corresponds to a “fourth unit”.

  The decoding processing unit 222 decodes the read digital data Dy into a digital signal Dx based on a predetermined codec (that is, conversion method: here, decompression processing of audio compression data). This codec is, for example, a GSM-AMR audio codec. The decoding processing unit 222 outputs the decoded digital signal Dx to the D / A conversion unit 221.

  The timing control unit 227 controls the timing at which the frame analysis unit 224 starts writing the digital data Dy into the storage unit 223 and the timing at which the decoding processing unit 222 starts reading out the digital data Dy from the storage unit 223. . At this time, the timing control unit 227 synchronizes the timing at which writing to the storage unit 223 is started with the timing at which reading from the storage unit 223 is started. Note that the timing at which reading from the storage unit 223 is started may be at the same time as or later than the timing at which writing to the storage unit 223 is started. In addition, the timing control unit 227 may be included in one of the configurations of the frame analysis unit 224 and the decoding processing unit 222 so as to control the timing at which the other configuration starts processing based on an instruction of the configuration. .

  When receiving the digital signal Dx from the decoding processing unit 222, the D / A conversion unit 221 performs D / A conversion of the received digital signal Dx into an analog audio signal AF4. The D / A converter 221 outputs the audio signal AF4 to the measuring unit 4.

  Reference is now made to FIG. The measurement unit 4 receives the audio signal AF3 from the test signal generation unit 1. Further, the measurement unit 4 receives the audio signal AF4 output from the D / A conversion unit 221 of the reception unit 22. The measuring unit 4 compares the waveform of the audio signal AF3 and the waveform of the audio signal AF4, and measures the delay time between the two waveforms.

  Next, a series of operations of the mobile communication terminal test system according to the present embodiment will be described with reference to FIG. FIG. 6 is a flowchart showing a flow of a series of processes of the mobile communication terminal test system.

(Step S21)
The test signal generator 1 generates a test analog audio signal AF3. The test signal generation unit 1 outputs the generated audio signal AF3 to the terminal under test 3 and the measurement unit 4. The terminal under test 3 receives the audio signal AF3 via an input unit such as a microphone.

(Step S22)
The terminal under test 3 converts the received voice signal AF3 into a carrier wave RF by encoding based on a predetermined communication method, and transmits the carrier wave RF to the receiving unit 22. The carrier wave RF transmitted from the terminal under test 3 is input to the frequency converter 226.

(Step S23)
The frequency converter 226 converts the frequency of the carrier wave RF based on a predetermined communication method. The frequency converter 226 outputs the frequency-converted carrier wave RF, that is, the analog signal Ax, to the A / D converter 225.

  When the analog signal Ax is received from the frequency converter 226, the A / D converter 225 A / D converts the received analog signal Ax into a digital signal. The A / D conversion unit 225 outputs the frame data Dz to the frame analysis unit 224.

  When the frame analysis unit 224 receives the frame data Dz from the A / D conversion unit 225, the frame analysis unit 224 demodulates the received frame data Dz based on a modulation method according to a predetermined communication method, and extracts the digital data Dy.

(Step S24)
In response to the instruction from the timing control unit 227, the frame analysis unit 224 starts writing the digital data Dy to the storage unit 223. At this time, the frame analysis unit 224 writes the extracted digital data Dy into the storage unit 223 for each block, with data of a predetermined unit U2 as one block.

(Step S25)
Upon receiving an instruction from the timing control unit 227, the decoding processing unit 222 starts reading the digital data Dy stored in the storage unit 223. At this time, the decoding processing unit 222 reads the digital data Dy for each block, with the data of the predetermined unit U1 as one block in the order stored in the storage unit 223. At this time, the timing control unit 227 includes a timing at which the frame analysis unit 224 starts writing the digital data Dy to the storage unit 223, and a timing at which the decoding processing unit 222 starts reading the digital data Dy from the storage unit 223. Synchronize.

(Step S26)
The decoding processing unit 222 decodes the read digital data Dy into a digital signal Dx based on a predetermined codec (that is, conversion method: here, decompression processing of audio compression data). The decoding processing unit 222 outputs the decoded digital signal Dx to the D / A conversion unit 221.

  When receiving the digital signal Dx from the decoding processing unit 222, the D / A conversion unit 221 performs D / A conversion of the received digital signal Dx into an analog audio signal AF4. The D / A converter 221 outputs the audio signal AF4 to the measuring unit 4.

(Step S27)
The measurement unit 4 receives the audio signal AF3 from the test signal generation unit 1. Further, the measurement unit 4 receives the audio signal AF4 output from the D / A conversion unit 221 of the reception unit 22. The measuring unit 4 compares the waveform of the audio signal AF3 and the waveform of the audio signal AF4, and measures the delay time between the two waveforms.

  As described above, according to the base station simulation apparatus 2 according to the present embodiment, the timing at which the digital data Dy is written into the storage unit 223 and the timing at which the digital data Dy is read out from the storage unit 223 under the control of the timing control unit 227. Are synchronized. Thereby, the delay time until the base station simulation apparatus 2 receives the carrier wave RF and outputs the audio signal AF4 is kept constant at least for each communication method. Therefore, by calculating the delay time between the audio signal AF3 and the audio signal AF4 by the measuring unit 4, it is possible to accurately calculate the delay time of the terminal under test 3 from the calculated delay time.

DESCRIPTION OF SYMBOLS 1 Test signal generation part 2 Base station simulation apparatus 21 Transmission part 211 A / D conversion part 212 Encoding process part 213 Storage part 214 Frame generation part 215 D / A conversion part 216 Frequency conversion part 217 Timing control part 22 Reception part 221 D / A conversion unit 222 Decoding processing unit 223 Storage unit 224 Frame analysis unit 225 A / D conversion unit 226 Frequency conversion unit 227 Timing control unit 3 Terminal under test 4 Measurement unit

Claims (6)

A test signal generator (1) for generating an analog first test signal;
A base station simulator (2) for converting the first test signal into a radio signal of a designated communication method and outputting the radio signal to a terminal under test;
In response to the radio signal, the analog second test signal output from the terminal under test and the first test signal are received, and between the first test signal and the second test signal. A measurement unit (4) for measuring the time difference between
A mobile communication terminal test system for testing a plurality of types of terminals under test having different communication methods,
The base station simulator is
An A / D converter (211) for A / D converting the first test signal and outputting it as a digital signal;
A storage unit (213);
An encoding processing unit (212) that encodes the digital signal based on a predetermined conversion method to generate a series of digital data, and sequentially writes the digital data to the storage unit for each first unit;
A frame generation unit (214) that reads out the digital data from the storage unit for each second unit in the stored order and generates the frame data by processing the read digital data based on the designated communication method. )When,
A D / A converter (215) for converting the frame data into an analog baseband signal;
A frequency converter (216) that converts the frequency of the baseband signal according to the designated communication method and outputs the converted signal to a mobile communication terminal to be tested;
The timing at which the encoding processing unit starts writing the series of digital data to the storage unit and the timing at which the frame generation unit starts reading the series of digital data from the storage unit are synchronized. A timing control unit (217);
With
A mobile communication terminal test system, characterized in that a delay time until the base station simulator receives the first test signal and outputs the radio signal is kept constant in each communication method. A test signal generator (1) for generating an analog third test signal;
A base station simulator (2) that receives a radio signal output from a terminal under test that has received the third test signal, converts it to an analog fourth test signal based on a designated communication method, and outputs the analog test signal; ,
A measurement unit (4) that receives the third test signal and the fourth test signal and measures a time difference between the third test signal and the fourth test signal;
A mobile communication terminal test system for testing a plurality of types of terminals under test having different communication methods,
The base station simulator is
A frequency converter (226) that receives the radio signal, converts the frequency based on the designated communication method, and outputs the baseband signal;
A D / A converter (225) for A / D converting the baseband signal and outputting it as frame data;
A storage unit (223);
A frame analysis unit (224) that processes the frame data based on the designated communication method to extract a series of digital data, and sequentially writes the digital data to the storage unit every third unit;
A decoding processing unit (222) that reads out the digital data from the storage unit for each fourth unit in the stored order, decodes the digital data based on a predetermined conversion method, and outputs the digital signal;
A D / A converter (221) for converting the digital signal into the fourth test signal;
Timing at which the frame analysis unit synchronizes timing for starting writing the series of digital data to the storage unit and timing at which the decoding processing unit starts reading the series of digital data from the storage unit A control unit (227);
With
A mobile communication terminal test system, wherein a delay time until the base station simulator receives the radio signal and outputs the fourth test signal is kept constant in each communication method. An A / D converter (211) that receives an analog test signal, A / D converts the test signal, and outputs it as a digital signal;
A storage unit (213);
An encoding processing unit (212) that encodes the digital signal based on a predetermined conversion method to generate digital data, and sequentially writes the digital data to the storage unit for each first unit;
A frame generation unit (214) that reads out the digital data from the storage unit for each second unit in the stored order, and processes the read digital data based on a designated communication method to generate frame data When,
A D / A converter (215) for converting the frame data into an analog baseband signal;
A frequency converter (216) that converts the frequency of the baseband signal according to the designated communication method and outputs the converted signal to a mobile communication terminal to be tested;
The timing at which the encoding processing unit starts writing the series of digital data to the storage unit and the timing at which the frame generation unit starts reading the series of digital data from the storage unit are synchronized. A timing control unit (217);
A base station simulator. A frequency converter (226) that receives an analog radio signal from a mobile communication terminal to be tested, converts the frequency based on a designated communication method, and outputs the converted signal as a baseband signal;
A D / A converter (225) for A / D converting the baseband signal and outputting it as frame data;
A storage unit (223);
Processing based on the designated communication method from the frame data to extract digital data, and a frame analysis unit (224) that sequentially writes the digital data to the storage unit for each third unit;
A decoding processing unit (222) that reads out the digital data from the storage unit for each fourth unit in the stored order, decodes the digital data based on a predetermined conversion method, and outputs the digital signal;
A D / A converter (221) for converting the digital signal into an analog test signal;
Timing at which the frame analysis unit synchronizes timing for starting writing the series of digital data to the storage unit and timing at which the decoding processing unit starts reading the series of digital data from the storage unit A control unit (227);
A base station simulator. A test signal generating step for generating an analog first test signal;
An A / D conversion step of A / D converting the first test signal and outputting as a digital signal;
An encoding processing step of generating digital data by encoding the digital signal based on a predetermined conversion method;
A writing step of sequentially writing the digital data to the storage unit for each first unit;
In synchronization with the writing step, the digital data is read from the storage unit for each second unit in the stored order; and
A frame generation step of generating frame data by processing the read digital data based on a designated communication method;
A D / A conversion step of converting the frame data into an analog baseband signal;
A frequency conversion step of generating a radio signal by frequency converting the baseband signal according to the designated communication method, and outputting the radio signal to a mobile communication terminal to be tested;
In response to the radio signal, the analog second test signal output from the terminal under test and the first test signal are received, and between the first test signal and the second test signal. A measurement step for measuring the time difference between
A delay time measuring method comprising: A test signal generating step for generating an analog third test signal;
A frequency conversion step of receiving a radio signal output from the terminal under test that has received the third test signal, converting the frequency based on a designated communication method, and outputting as a baseband signal;
A D / A conversion step of A / D converting the baseband signal and outputting as frame data;
A frame analysis step of extracting the digital data by processing the frame data based on the designated communication method;
A writing step of sequentially writing the digital data to the storage unit for each third unit;
A step of reading out the digital data from the storage unit for each fourth unit in the order of storage in synchronization with the writing step;
Decoding processing step of decoding the read digital data based on a predetermined conversion method and outputting as a digital signal;
A D / A conversion step of converting the digital signal into the fourth test signal;
A measurement step of receiving the third test signal and the fourth test signal and measuring a time difference between the third test signal and the fourth test signal;
A delay time measuring method comprising:

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