JP5410574B2 - Signal measuring apparatus and method - Google Patents

Description

  The present invention measures the transmission timing of a mobile terminal such as a mobile phone that employs time division / synchronization / code division multiplexing as a communication method, and determines the quality of the operation of the mobile terminal based on the measurement result. The present invention relates to a signal measuring apparatus and method for displaying.

  Conventionally, a CDMA (Code Division Multiple Access) method, which is a communication method in which a single frequency band is efficiently shared by a plurality of users so that a large number of users can communicate simultaneously, is known. In the CDMA system, since a near / far problem may occur when a plurality of mobile terminals use one base station, it is a function for controlling the transmission power of the mobile terminal from the base station at a high speed in slot units. Closed loop power control (hereinafter referred to as CLPC) is used.

  In this CLPC, the base station measures the signal received from the mobile terminal, and based on the measurement result, the mobile terminal is configured to increase or decrease the transmission power of the mobile terminal by TPC (Transmitter Power Control) included in the downlink frame. In response to this instruction, the transmission power of the mobile terminal is controlled in units of uplink slots so that the signal is increased or decreased and output. As a mobile terminal transmission power measuring apparatus for performing such a CLPC function test, for example, one disclosed in Patent Document 1 below is known.

  FIG. 11 is a schematic block diagram of a mobile terminal transmission power measuring apparatus described in Patent Document 1 below. The connection terminal 101 a of the mobile terminal transmission power measuring apparatus 101 is connected to the mobile terminal 103 to be measured via the directional coupler 102 as a cord, and the transmission power requested to transmit to the mobile terminal 103. Power control setting means 104 for setting the number of changes and transmission power change amount, and control for controlling the setting of the transmission power change number and transmission power change amount transmitted from the mobile terminal 103 based on the setting information from the power control setting means 104 Unit 105, power control requesting means 106 for outputting a transmission request signal corresponding to the number of transmission power changes and the amount of transmission power controlled by control unit 105, and a transmission request signal from power control requesting means 106 In addition, the transmission power is adjusted according to the TPC bit information in each transmission slot. Transmitting means 107 for transmitting to the mobile terminal 103 under control of either up / down or maintaining the current status, and transmitting from the mobile terminal 103 in response to transmission from the transmitting means 107 in response to a transmission request by the power control requesting means 106 Receiving means 108 for receiving transmitted transmission power, an A / D converter 109 for converting the signal received by the receiving means 108 into a digital signal, and transmission from the mobile terminal 103 output from the A / D converter 109 A memory 110 for storing signal waveform data; a slot detection unit 111a for detecting a slot of the mobile terminal 103 from the waveform data stored in the memory 110; and the power of each slot detected by the slot detection unit 111a and the interval between the slots. Slot power detection means 111b for detecting the amount of power change of the slot, and slot detection means 111a And an analysis result memory 111c that stores the number of slots detected by the slot power detection means 111b, the power of each slot, and the amount of power change between slots, and information stored in the analysis result memory 111c and the power control setting means 104 When the setting information is compared and the number of slots matches, a determination means 112 for comparing the power for each slot and comparing the amount of change in power between the slots to determine the operation of the mobile terminal 103, and an analysis result memory The display control circuit 113 displays the content stored in 111c and the determination result of the determination unit 112 on the display 114.

  By the way, as a communication method for mobile terminals such as mobile phones, it is one of the 3rd generation (3G) mobile phone systems, and is a unique specification TD-SCDMA (Time Division-Synchronous Code) created for use in China. Division Multiple Access (Time Division / Synchronization / Code Division Multiple Access) method is known. In the normal CDMA system, the upstream and downstream channels using different frequency bands are unified using the same frequency in the TD-SCDMA system, and the upstream communication quality from the terminal to the base station is ensured. Therefore, the transmission timings of all mobile terminals under the base station that transmit the radio frame are synchronized in units of chips (1/8 chip), or by using a technology such as a high-function antenna, CDMA technology and uplink and downlink Is a communication method that mixes and uses time division duplex (TDD) technology that performs communication by switching in a time division manner.

JP 2003-46431 A

  Thus, in the case of a mobile terminal whose communication system is the CDMA system, an apparatus for checking the operation of the target mobile terminal based on the TPC measurement standard for controlling the power of the measurement signal from the mobile terminal (A mobile terminal transmission power measuring device of Patent Document 1) is known.

By the way, in a mobile terminal of a time division / synchronization / code division multiplexing system such as a TD-SCDMA system, a single frequency is divided into time slots and a plurality of mobile terminals are allocated by code division. It is essential to control and synchronize the uplink transmission timing to the base station in units of chips (1 chip = about 0.78 μs) for each mobile terminal.
Therefore, in a mobile terminal that employs time division / synchronization / code division multiplexing, the operation of the mobile terminal is checked by measuring the transmission timing of the uplink signal from the mobile terminal to be measured. However, since no measurement standard for this measurement has been established at present, it is desired to develop an apparatus that can check the operation of a mobile terminal based on the measurement result.

  Therefore, the present invention has been made in view of the above problems, and measures the transmission timing of a mobile terminal using a time division / synchronization / code division multiplexing system as a communication system, and based on the measurement result, It is an object of the present invention to provide a signal measuring apparatus and method capable of determining the quality of operation and displaying the measurement result.

In order to achieve the above object, the signal measuring apparatus according to claim 1 communicates with the mobile terminal 20 to be measured by time division / synchronization / code division multiplexing, and the mobile terminal A signal measuring device 1 for measuring the signal of
A transmission unit 13 for continuously transmitting a timing control command for controlling transmission timing of the mobile terminal to the mobile terminal a plurality of times;
The transmission timing of the signal transmitted from the mobile terminal according to the timing control command is measured, and the time slot to which the mobile terminal is assigned from the signal from the mobile terminal and a predetermined time slot from the time slot a measurement unit 16 for calculating a difference between the transmission timing of the number of intervals apart time slots as the offset of the transmission timing between timeslots,
A display unit 19 for displaying a measurement result measured by the measurement unit;
A display control unit 18 configured to continuously display a shift amount of transmission timing between the time slots calculated by the measurement unit in time series and display the graph on the display unit;
It is provided with.

  The signal measuring device according to claim 2 is the signal measuring device according to claim 1, further comprising a setting operation unit 11 for setting the number of intervals, wherein the measurement unit 16 is set by the setting operation unit. The deviation amount is calculated according to the number of intervals.

Signal measuring device according to claim 3, wherein, in the signal measuring device according to claim 1 or 2, wherein said measuring section 16, the tolerance range of the shift amount or RaTadashi rated value of the transmission timing between the calculated time slot Calculate the error value by subtracting the reference value that is the intermediate value of
The display control unit 18 is characterized in that the error values calculated by the measurement unit are continuously arranged in time series and displayed on the display unit 19 as a graph.

The signal measuring device according to claim 4 is the signal measuring device according to any one of claims 1 to 3,
When the measurement unit 16 displays the calculated deviation amounts in time series, for each of the arranged deviation amounts, calculate a difference from the adjacent previous deviation amount,
The display control unit 18 is characterized in that the difference of the deviation amount calculated by the measurement unit is arranged in time series and displayed on the display unit 19 as a graph.

The signal measurement device according to claim 5 is the signal measurement device according to any one of claims 1 to 4, wherein the timing control command transmitted to the mobile terminal 20 delays at least the transmission timing from the mobile terminal. A timing control command and a timing control command for advancing transmission timing from the mobile terminal,
The transmission timing of the signal transmitted from the mobile terminal corresponding to each timing control command measured by the measurement unit 16 is compared with the standard value corresponding to each command, and the transmission timing is It is characterized by having a determination unit 17 for determining whether or not it is within an allowable error range of the standard value.

  The signal measurement device according to claim 6 is the signal measurement device according to claim 5, wherein the display control unit 18 is normal or abnormal in the deviation amount or the error value calculated by the measurement unit 16. A standard line obtained from the standard value for determining whether or not is overlaid on the graph is displayed.

  The signal measurement device according to claim 7 is the signal measurement device according to claim 5 or 6, wherein the transmission timing determined by the determination unit 17 is within an allowable error range of the standard value. Based on the determination result, the transmission timing determined to be normal and the transmission timing determined to be abnormal are displayed in an identifiable manner in the graph.

The signal measurement method according to claim 8 is a signal measurement method for measuring a signal from the mobile terminal by communicating with the mobile terminal 20 to be measured by time division / synchronization / code division multiplexing. There,
Transmitting a timing control command for delaying the transmission timing from the mobile terminal or a timing control command for advancing the transmission timing to the mobile terminal, and matching the transmission timing from the mobile terminal with a reference timing When,
Transmitting a timing control command for maintaining the transmission timing from the mobile terminal to the mobile terminal continuously several times;
Transmitting a timing control command for delaying the transmission timing from the mobile terminal to the mobile terminal continuously several times;
Transmitting a timing control command for advancing the transmission timing from the mobile terminal to the mobile terminal a plurality of times in succession;
Receiving a signal transmitted from the mobile terminal in response to each command;
Measuring the transmission timing of the received signal;
Determining whether the measured transmission timing falls within the allowable error range of the set regulations rated value,
Shift amount of the transmission timing between the from the signal from the mobile station and the mobile station is allocated a time slot, the time slot data the difference between the transmission timing of the predetermined number of intervals apart time slots from time slot As a step of calculating as
And displaying the graph on the display unit 19 chronologically arranged continuously shift amount of the transmission timing between the calculated issued said time slots,
It is characterized by including.

  According to the signal measuring apparatus of the present invention, a timing control command for controlling transmission timing is transmitted to a mobile terminal to be measured, a signal for the timing control command is received from the mobile terminal, and the received signal By measuring the transmission timing, it is possible to easily measure the transmission timing synchronization that is important for a mobile terminal adopting the time division / synchronization / code division multiplexing method as a communication method and grasp the measurement result. it can.

  In addition, the measured transmission timings are arranged in time series and displayed in a graph, and the measured transmission timing deviation amount and a graph obtained from an error value based on the deviation amount are arbitrarily selected to display a predetermined display area. Therefore, the operator can easily observe the transmission timing of the mobile terminal that is the measurement target.

  Furthermore, since the standard line obtained from the preset standard value is displayed in the graph related to the deviation amount of the transmission timing displayed on the display unit, the operator can determine whether the transmission timing is normal or abnormal in the graph. Can be easily determined. Further, when an abnormality occurs in the transmission timing, the corresponding part is displayed so as to be identifiable, for example, by color-coded display or blinking display, so that the operator can further reliably identify the abnormal part.

FIG. 4 is an explanatory diagram of a frame format of a time division / synchronization / code division multiplexing system which is a communication system of a mobile terminal used in the present invention. It is a schematic block diagram for demonstrating the structure of the signal measuring apparatus which concerns on this invention. It is explanatory drawing for demonstrating the standard value of SScommand which controls transmission timing in the time division / synchronization / code division multiplexing system used by this invention. It is explanatory drawing for demonstrating SSbit which is the command command in the same SScommand. It is a conceptual diagram for demonstrating the process in the slot extraction means which comprises the signal measuring device which concerns on this invention. It is the example of a display which displayed the measurement result in the signal measuring device concerning the present invention. It is another example of a display which displayed the measurement result in the signal measuring device concerning the present invention. It is another example of a display which displayed the measurement result in the signal measuring device concerning the present invention. It is another example of a display which displayed the measurement result in the signal measuring device concerning the present invention. It is a flowchart figure for demonstrating the processing operation of the signal measuring apparatus which concerns on this invention. It is a schematic block diagram which shows the structure of the conventional power measuring apparatus.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings. In addition, the present invention is not limited by this embodiment, and all other forms, examples, operation techniques, and the like that can be implemented by those skilled in the art based on this form are included in the scope of the present invention. .

  The signal measurement device of this example has a function as a pseudo base station device that impersonates a real network, communicates with a mobile terminal to be measured in a time division / synchronization / code division multiplexing system, and moves Transmits a timing control command for controlling the transmission timing from the terminal to the mobile terminal, receives a signal corresponding to the command from the mobile terminal, and measures the transmission timing of the signal received from the mobile terminal In addition, the display based on the measurement result is performed.

  In the following description, a TD-SCDMA (Time Division-Synchronous Code Division Multiple Access) system, which is a time division / synchronization / code division multiplexing system, will be described as a mobile terminal communication system. As long as it is assigned to user's uplink / downlink signals to a time slot that is cut short with the same carrier frequency channel, and the uplink signal from the mobile terminal is synchronized, the communication is performed by switching the time slot and performing mutual transmission. There is no particular limitation.

  First, a TD-SCDMA system used as a communication system of the mobile terminal 20 that is a measurement target of the signal measuring apparatus 1 of this example will be described. The TD-SCDMA system is a communication system that combines a CDMA technique and a time division duplex (TDD) technique for performing communication by switching between uplink and downlink in a time division manner.

  FIG. 1 shows a TD-SCDMA frame format. As shown in the figure, a TD-SCDMA signal is composed of periodic time units. First, a basic time unit is called “Radio frame” (hereinafter referred to as a radio frame), and the length of each radio frame is 10 ms (chip rate = 1.28 Mcps (12800 chips)). Each radio frame is divided into two “Sub-frames” (hereinafter referred to as subframes) each having a length of 5 ms (chip rate = 6400 chips).

  This subframe includes a standard time slot TS # 0 dedicated to the downlink (communication from the base station to the mobile terminal 20) TS # 0, a special slot, and six normal time slots TS # 1 to TS # 6 ( Chip rate = 864 chips), and transmission data is transmitted in a normal slot. Of TS # 1 to TS6, TS # 1 is assigned to the uplink (communication from the mobile terminal 20 to the base station), and TS # 2 to # 6 are flexible (for example, to the uplink / downlink). TS # 1 to TS3 can be assigned to the uplink, and TS # 4 to TS6 can be assigned to the downlink.

  The three special slots include a downlink pilot time slot (DwPTS: Downlink Pilot Times Slot, chip rate = 96 chips), an uplink pilot time slot (UpPTS: Uplink Pilot Times Slot, chip rate = 160 chips), and DwPTS. A guard period (GP, chip rate = 96 chips) for taking a connection margin is included between the FP and UpPTS. This is for downlink and uplink frequency synchronization and for providing a guard gap from the downlink to the uplink.

  Of the TS # 1 to TS # 6, the time slot used for the downlink includes an SS symbol (s) area as shown in the figure. In the SS symbol (s) area, SS (Synchronization Shift) command, which is a timing control command for controlling the transmission timing of the mobile terminal 20 with 1/8 chip (about 0.1 μs), is included. This SS command is transmitted for each mobile terminal 20 that is code-divided for each time slot, and the base station transmits this SS command to the mobile terminal 20 so that the uplink transmission timing of the mobile terminal 20 is advanced / The transmission timing is synchronized by controlling the delay.

  Next, the configuration of the signal measuring apparatus of this example will be described with reference to FIG. 2 includes a setting operation unit 11, a control unit 12, a transmission unit 13, a directional coupler 14, a reception unit 15, a measurement unit 16, a determination unit 17, a display control unit 18, and a display unit 19. Is done. Hereinafter, each component will be described in detail.

  As shown in FIG. 2, the connection terminal 1 a of the signal measurement device 1 can be connected to the mobile terminal 20 to be measured by a coaxial cable, and the transmission unit 13 and the reception unit via the directional coupler 14. 15 respectively. In addition, the mobile terminal 20 may be configured to be wirelessly connected to the signal measuring device 1 via an antenna.

  The setting operation unit 11 is a measurement method for measuring the transmission timing of the mobile terminal 20 (that is, the number of times of transmission timing control executed in each of a feedback section, a maintenance section, a delay section, and an advanced section described later, (Specification of measurement such as order of each section), setting of time slot in subframe to which mobile terminal 20 to be measured is assigned, and undefined SS command transmitted when checking operation of mobile terminal 20 Setting for executing Step for transmitting, setting of the number of times of control for transmitting undefined SS command, and calculating a deviation amount of transmission timing of a specific time slot and a time slot separated from this time slot by a predetermined interval Setting of a predetermined number of time slot intervals (arbitrary natural number), S transmitted to the mobile terminal 20 as shown in FIG. In addition to setting command standard values (values indicating the normal measurement range of signal transmission timing from the mobile terminal 20), selection of display contents to be displayed on the display unit 19, and instructions for starting / stopping the transmission timing measurement test Various information necessary for driving the signal measuring apparatus 1 is set and selected.

Based on the specification of the measurement method set by the setting operation unit 11, the control unit 12 transmits a command for transmitting SS command which is a timing control command for controlling the transmission timing of the mobile terminal 20 to be measured. Is output. Note that the measurement method that is the basis of the command to the transmission unit 13 is stored in a storage unit (not shown) included in the control unit 12.
Further, the control unit 12 determines whether or not the control unit 12 has been executed a number of times of control based on the specification of the measurement method set in advance based on the measurement result of the transmission timing from the measurement unit 16. When it is determined that the transmission timing control has been executed a predetermined number of times, a command is transmitted to the transmission unit 13 for performing the next processing based on the specification of the set measurement method.

  Further, the control unit 12 receives the measurement result of the transmission timing of the time slot from the measurement unit 16, and based on this measurement result, the transmission timing determined for each time slot to which the mobile terminal 20 to be measured is assigned (that is, A reference timing (target) is set as a reference for the transmission timing to be raised by the mobile terminal 20 as viewed from the signal measuring apparatus 1 which is a pseudo base station. Furthermore, when the number of undefined SScommands to be controlled and the execution of undefined sections are set from the setting operation unit 11, the control unit 12 sends a command for transmitting the undefined SScommand to the mobile terminal 20. The data is transmitted to the transmission unit 13.

  The control unit 12 outputs a signal notifying the measurement start to the measurement unit 16 and outputs a signal notifying the end of the measurement, control for setting the reception frequency for the reception unit 15, set by the setting operation unit 11 Control that outputs a standard value, the number of time slot intervals, a reference value obtained from the standard value (an intermediate value of an allowable error range of the standard value), etc. to the measurement unit 16, the determination unit 17, and the display control unit 18, and the selected display In addition to controlling the contents to be output to the display control unit 18, each part of the signal measuring device 1 is controlled.

  The command transmitted from the control unit 12 to the transmission unit 13 is a timing control command for delaying the transmission timing from the mobile terminal 20 or the mobile terminal 20 so that the transmission timing from the mobile terminal 20 matches the reference timing. A command for transmitting a timing control command for advancing the transmission timing from the mobile station, a command for transmitting a timing control command for maintaining the transmission timing from the mobile terminal 20, and a timing for delaying the transmission timing from the mobile terminal 20 A command for transmitting a timing control command and a command for transmitting a timing control command for advancing the transmission timing from the mobile terminal 20, which differ depending on the measurement method specification set in the setting operation unit 11. Timing control for delaying transmission timing from the mobile terminal 20 Instructions for transmitting a decree includes instructions for transmitting the timing control command for advancing the transmission timing from the mobile terminal 20. Accordingly, the measurement method set by the setting operation unit 11 also includes at least processing for transmitting a timing control command for delaying the transmission timing of the mobile terminal 20 and processing for transmitting a timing control command for advancing the transmission timing of the mobile terminal 20. It becomes a measuring method including.

  The transmission unit 13 includes a timing control request unit 13a and a transmission circuit 13b. Under the control of the control unit 12, the transmission unit 13 transmits control information including SS command for controlling transmission timing to the mobile terminal 20.

  When the timing control request means 13a inputs a command for transmitting a timing control command from the control unit 12, in accordance with this command, the SS command command SSbits (modulation method is QPSK (quadrature), which is the timing control command shown in FIG. In the case of phase shift keying), 00: Down (delay), 11: Up (advance), 01: Do nothing (maintain), and when the modulation method is 8 PSK (8 phase shift keying), 00: Down (delay) 11: Up (advance) and 01: Do nothing (maintain)) are sequentially output to the transmission circuit 13b.

  That is, a timing control command for delaying the transmission timing from the mobile terminal 20 or a timing control command for advancing the transmission timing from the mobile terminal 20 to transmit the transmission timing from the mobile terminal 20 to the reference timing is transmitted. If a command to be transmitted is input, an SSbit of Down (delay) or Up (advance) based on the current transmission timing and reference timing, and a command to transmit a timing control command for maintaining the transmission timing from the mobile terminal 20 If entered, the SS bit of Do nothing (maintenance), if the command for transmitting the timing control command for delaying the transmission timing from the mobile terminal 20 is input, the SS bit of Down (delay), the transmission from the mobile terminal 20 When a command that sends a timing control command to advance timing is input Are sequentially outputs control information carrying the SSbit of Up (lead) to the transmitting circuit 13b.

Furthermore, when a command for transmitting an undefined SS command to the mobile terminal 20 is input from the control unit 12 to the timing control request unit 13a, an SS bit (for example, an undefined SS command command command) is input according to the command. When the modulation method is QPSK, control information carrying 10: (undefined) or the like is sequentially output to the transmission circuit 13b.
The timing control request unit 13a outputs a trigger signal that prompts the measurement unit 16 to start measurement at the timing when the control information is output to the transmission circuit 13b.

  The transmission circuit 13b sequentially outputs the control information output from the timing control request unit 13a to the mobile terminal 20 via the directional coupler 14 and the connection terminal 1a. When receiving the control information from the transmission circuit 13b, the mobile terminal 20 transmits a signal whose transmission timing is controlled in accordance with an SS command command included in the control information to the signal measuring apparatus 1.

  The receiving unit 15 includes a receiving circuit 15a, an A / D converter 15b, and a data storage unit 15c, and receives a signal transmitted from the mobile terminal 20 by the receiving circuit 15a via the directional coupler 14. The received data obtained by converting the received signal into a digital signal by the A / D converter 15b is stored in the data storage means 15c.

  Note that the data storage unit 15c has a function of independently reading and writing data, and from receiving a signal notifying the start of measurement from the control unit 12 until receiving a signal notifying the end of measurement. Meanwhile, the converted received data is continuously stored.

  The measurement unit 16 is configured by a microcomputer such as a DSP (Digital Signal Processor), and includes a slot extraction unit 16a, a slot timing calculation unit 16b, and a measurement result storage unit 16c. The transmission timing based on the received signal from the mobile terminal 20 is measured.

  When the trigger signal from the timing control requesting unit 13a is input, the slot extracting unit 16a reads the received data stored in the data storage unit 15c in the stored order, and among the received data, the mobile terminal 20 to be measured. Only the received data of a specific time slot to which is assigned is extracted and output to the slot timing calculation means 16b and the measurement result storage means 16c.

  That is, conceptually, as shown in FIG. 5, the received data stored in the data storage unit 15c is read in the order of storage, and the mobile terminal 20 to be measured is assigned to the received data. The received data of only the time slot (TS # 1 in the figure) is extracted.

The slot timing calculation unit 16b calculates the transmission timing of the reception data extracted by the slot extraction unit 16a. Further, the slot timing calculation means 16b calculates the difference in transmission timing between the time slots based on the calculated transmission timing and the difference in transmission timing between a specific time slot and a time slot that is a predetermined number of intervals away from the time slot. It is calculated as a transfer amount.
The interval number of the time slot is an arbitrary natural number set by the setting operation unit 11. However, when there is no designation, processing is performed with the interval number = 1.

  Further, the slot timing calculation means 16b calculates an error value obtained by subtracting the reference value from the calculated transmission timing deviation amount. Information on the reference value used in the slot timing calculation unit 16b is notified from the control unit 12. Further, the slot timing calculation means 16b calculates a difference in the amount of transmission timing deviation between a specific time slot and a time slot that is a predetermined number of intervals away from the time slot.

  The measurement result storage means 16c receives the reception data of the time slot extracted by the slot extraction means 16a, the transmission timing of the time slot calculated by the slot timing calculation means 16b, a specific time slot and a predetermined number of intervals away from this time slot. The transmission timing deviation amount calculated from the transmission timing with respect to the time slot, the transmission timing error value obtained by subtracting the reference value from the deviation amount, the difference in the deviation amount of the received data, and the like are stored.

The determination unit 17 compares the transmission timing deviation amount stored in the measurement result storage unit 16c with the transmission timing standard value (shown in FIG. 3) set by the setting operation unit 11, and transmits the transmission timing deviation. It is determined whether or not the amount is within an allowable error range of the standard value. As a result, it can be determined whether or not the transmission function of the mobile terminal 20 to be measured is normal, so that the mobile terminal 20 can be checked for operation (transmission timing quality determination).
As an example of determination, for example, as shown in FIG. 3, the standard value of the deviation amount from the slot of the adjacent subframe (number of intervals = 1) when the transmission timing is controlled in the delay direction (SSbit = 11). If the upper limit value is −1/16 chip and the lower limit value is −3/16 chip, it is determined that it is normal if it is −2/16 chip, and abnormal if it is −4/16 chip.

  Further, when the determination unit 17 transmits an undefined SS command to the mobile terminal 20, whether or not the transmission timing from the mobile terminal 20 is changed by the transmitted undefined SS command (normally, Because the SS command is undefined, the transmission timing is not controlled and the current state is maintained). That is, since it is possible to determine whether or not the mobile terminal 20 malfunctions based on the undefined SS command, the operation of the mobile terminal 20 can be confirmed.

  The display control unit 18 includes a difference in transmission timing deviation amount, error value (a value obtained by subtracting the reference value from the deviation amount), and received data deviation amount stored in the measurement result storage unit 16c. Are generated, and the display data for displaying the graphs in time series is generated and output to the display. When the display control unit 18 receives information on the time slot determined to be abnormal by the determination unit 17, the display control unit 18 displays the information in an identifiable manner in the graph. When the display control unit 18 receives the standard value information from the control unit 12, the standard is displayed in the graph. A standard line 36 obtained from the values is displayed.

  The display unit 19 is configured by a display device such as a liquid crystal display, for example, and the display content selected by the setting operation unit 11 under the control of the display control unit 18 (various measurements related to the transmission timing of the mobile terminal 20 to be measured). The result and the determination result in the determination unit 17 are displayed.

  Here, display examples of the display data created by the display control unit 18 will be described with reference to FIGS. In each display example, processing is performed in the order of the feedback section, the maintenance section, the delay section, the advance section, and the undefined section, and the number of transmission timing control times in the maintenance section, the delay section, and the advance section is six times, and the deviation amount The number of time slot intervals when calculating is set to 1 (that is, the transmission timing of adjacent time slots).

  In addition, the display example described below is an example of the measurement method described above. Therefore, the combination of display areas, the display method, the standard value, the number of time slot intervals, and the like are displayed before or during display on the display unit 19. By arbitrarily setting from the setting operation unit 11, the display contents desired by the operator can be displayed.

  In the display example of FIG. 6, a transmission timing graph display area 31, a section display area 32, and a deviation amount graph display area 33 are displayed on the display screen.

  In the transmission timing graph display area 31, with respect to the transmission timing calculated by the slot timing calculation means 16b, the horizontal axis represents n (number of slots to be measured), and the vertical axis represents the time lag with respect to the reference timing as delay / advance. Timing errors (unit: chip) are shown, and the transmission timings of a specific time slot are displayed continuously in time series.

  The section display area 32 is a display area for allowing the operator to grasp which section the measurement result is divided into. Here, the area is divided into five sections A to E, Step A is a feedback section that performs control to match the current transmission timing of the mobile terminal 20 to be measured to the reference timing, and Step B is the transmission timing. A control section that performs control to maintain (in the example shown, control to maintain the reference timing), Step C is a delay section that performs control to delay the transmission timing a predetermined number of times in the delay direction, and Step D is control that advances the transmission timing a predetermined number of times in the forward direction. Step E is an undefined section in which Step E is transmitted to an undefined SS command to the mobile terminal 20 to check whether the transmission timing has changed.

  The deviation amount graph display area 33 is a time series of the previous slot with n as the horizontal axis (number of slots to be measured) and the vertical axis as the deviation amount (Δt, unit is chip) with respect to the reference timing. The deviation amounts are displayed side by side in a continuous manner so that they can be easily compared with the display contents of the transmission timing graph display area 31. In the example in the figure, the deviation amount is calculated by taking a positive number.

  Specifically, in a section (Step C) in which the transmission timing of the mobile terminal 20 is delayed, the difference between the transmission timings of the two time slots is multiplied by −1 to obtain a positive deviation amount. In a section in which the transmission timing is advanced or maintained (Step A, Step B, Step D), the difference between the transmission timings of the two time slots is multiplied by 1 (that is, as it is), and is a positive shift Calculated as a quantity. Note that the feedback interval of Step A may be controlled in the delay direction. In this case, the difference between the transmission timings of the two time slots is calculated by multiplying by −1 to obtain a positive deviation amount. In this way, by displaying the shift amount as a positive number, the display area of the shift amount graph display area 33 on the display screen can be made smaller than when displaying the positive and negative values.

In FIG. 6, in the section of Step A (feedback section), control for returning the transmission timing of the signal transmitted from the mobile terminal 20 to the reference timing (that is, delaying the transmission timing based on the current transmission timing and the reference timing) Control to advance). When the transmission timing of the mobile terminal 20 is controlled with high accuracy, the display of the transmission timing graph display area 31 is a horizontal straight line with “Target” as the reference timing, and the display of the deviation amount graph display area 33 is “ “0” is displayed as a horizontal straight line graph.
In the figure, since the transmission timing is delayed from the reference timing, the transmission timing graph display area 31 is displayed as “Target” because the transmission timing is controlled to advance by 1/8 chip in the advance direction. After increasing by 1/8 chip until it becomes, a horizontal straight line graph is displayed, and the display of the shift amount graph display area 33 is displayed as a horizontal straight line graph at “0” after 1/8 chip is lowered.

In the Step B section (maintenance section), when it is confirmed in Step A that the transmission timing of the mobile terminal 20 is controlled to the reference timing, control is performed to maintain the transmission timing of the mobile terminal 20 at the reference timing. When the transmission timing of the mobile terminal 20 is controlled with high accuracy, the display of the transmission timing graph display area 31 is a horizontal straight line with “Target” as the reference timing, and the display of the deviation amount graph display area 33 is “ “0” is displayed as a horizontal straight line graph.
In the figure, since the transmission timing is controlled with high precision, the display of the transmission timing graph display area 31 is “Target” and is a horizontal straight line, and the display of the deviation amount graph display area 33 is “0” and the horizontal straight line. It is displayed as a graph.

In the Step C section (delay section), when it is confirmed in Step B that the transmission timing of the mobile terminal 20 is controlled to the reference timing, the transmission timing of the mobile terminal 20 is controlled to be delayed by 6 times by 1/8 chip. . When the transmission timing of the mobile terminal 20 is controlled with high accuracy, the display in the transmission timing graph display area 31 is a graph that decreases in steps by 1/8 chip from the reference timing, and the display in the deviation amount graph display area 33 is “ After increasing 1/8 chip from "0", it is displayed as a horizontal straight line graph.
In the figure, since the transmission timing is controlled with high precision, the display in the transmission timing graph display area 31 is a graph that falls in a stepped manner by 1/8 chip from the reference timing, and the display in the deviation amount graph display area 33 is “0”. ”Is displayed as a horizontal straight line after 1/8 chip.

In the Step D section (advance section), when it is confirmed in Step C that control for delaying the transmission timing of the mobile terminal 20 by 6 times by 1/8 chip is performed, the transmission timing of the mobile terminal 20 is set by 6 times by 1/8 chip. Control to advance. When the transmission timing of the mobile terminal 20 is controlled with high accuracy, the display of the transmission timing graph display area 31 is a graph that rises in steps by 1/8 chip from the reference timing, and the display of the deviation amount graph display area 33 is StepC. The graph is displayed as a horizontal straight line while maintaining the same position as the graph.
In the figure, the accuracy of the transmission timing is poor, so that there is a large disturbance without stepping up by 1/8 chip, and both the transmission timing graph display area 31 and the deviation amount graph display area 33 form unique graph shapes. doing. In addition, since there is a part where the transmission timing is out of the allowable error range of the standard value, the transmission timing graph display area 31 can be identified by, for example, color-coded display or blinking display with a point where the transmission timing is disturbed as a point. The shift amount graph display area 33 displays the position corresponding to the point a as the point b so that the disturbance of the transmission timing can be identified in the same manner as the point a.

In the Step E section (undefined section), when it is confirmed in Step C that the transmission timing of the mobile terminal 20 is advanced 6 times by 1/8 chip, an undefined SS command of the mobile terminal 20 is set. Processing for transmitting the control information and confirming whether or not the mobile terminal 20 malfunctions is performed. If the function of the mobile terminal 20 is normal, the mobile terminal 20 does not operate according to undefined SS command. Therefore, the display of the transmission timing graph display area 31 becomes a horizontal straight line graph with the reference timing “Target”, and the deviation amount graph display area 33 is “0” and is displayed as a horizontal straight line graph.
In the figure, since the function of the mobile terminal 20 is normal, the display of the transmission timing graph display area 31 is “Target” and becomes a horizontal straight line graph, and the display of the deviation amount graph display area 33 is “0” and the horizontal straight line. It is displayed as a graph.

The display example shown in FIG. 7 displays the same contents as the transmission timing graph display area 31 and the section display area 32 displayed in FIG. 6, and the deviation displayed in the deviation amount graph display area 33 in FIG. This is an example in which the amount is displayed in positive and negative and the standard line 36 obtained from the standard value set by the setting operation unit 11 is displayed in Step B, Step C, and Step D.
In the following description, since the transmission timing graph display area 31 and the section display area 32 are the same as those in FIG. 6, the description thereof will be omitted, and only the description of the shift amount graph display area 33 having different display contents will be described.

  The standard line 36 displayed in the graph of the deviation amount graph display area 33 is a line obtained from the standard value shown in FIG. 3, and since the upper limit value / lower limit value differs depending on SSbit of SS command, the upper limit value in each step. And standard lines 36 corresponding to the lower limit values are displayed in the respective sections. Note that the standard line 36 can be arbitrarily set by the operation from the setting operation unit 11 to indicate whether or not the standard line 36 is displayed, and to select a section in which the standard line 36 is displayed.

  In the Step B section (maintenance section), two standard lines 36 of 1/16 chip as the upper limit value and −1/16 chip as the lower limit value are displayed. In the Step B section, the transmission timing of the mobile terminal 20 to be measured does not deviate from the two standard lines 36 and is within the allowable error range of the standard value, so the mobile terminal 20 in the Step B section. Can be determined to be normal.

  In the Step C section (delay section), two standard lines 36 having an upper limit value of −1/16 chip and a lower limit value of −3/16 chip are displayed. In the Step C section, the transmission timing of the mobile terminal 20 to be measured does not deviate from the two standard lines 36 and is within the allowable error range of the standard value. Therefore, the mobile terminal 20 in the Step C section. Can be determined to be normal.

  In the StepD section (advanced section), two standard lines 36 having an upper limit value of 3/16 chip and a lower limit value of 1/16 chip are displayed. In the section of StepD, it can be seen that the transmission timing of the mobile terminal 20 to be measured exceeds the upper limit value of the standard value, and an abnormality has occurred in the transmission timing. Accordingly, it can be determined that the transmission timing of the mobile terminal 20 in Step D is abnormal. In addition, the transmission timing graph display area 31 displays a point where the transmission timing is disturbed as a point c so that it can be identified, for example, by color display or blinking display, and the shift amount graph display area 33 indicates a position corresponding to the point c. Disturbance of transmission timing is displayed as a d point so as to be identifiable like the c point.

  The display example shown in FIG. 8 shows an error value in which an error value obtained by subtracting a reference value that is an intermediate value of an allowable error range of a standard value set by the setting operation unit 11 from a deviation amount is continuously arranged in time series. In this example, the graph display area 34 is displayed, and the standard line 36 obtained by subtracting the reference value from the standard value set by the setting operation unit 11 is displayed in Step B, Step C, and Step D.

  A standard line 36 in FIG. 8 is a standard line for the deviation amount error value, where “0” is a reference value that is an intermediate value of the standard allowable range of the standard value, and an upper limit value and a lower limit value from the reference value are set. Each one is represented. In this display example, normally, when the transmission timing of the mobile terminal 20 is controlled with high accuracy, the reference value “0” is displayed, and if there is any abnormality, the display is shifted from “0”. Note that the standard line 36 can be arbitrarily set by the operation from the setting operation unit 11 to indicate whether or not the standard line 36 is displayed, and to select a section in which the standard line 36 is displayed.

  In the Step B section (maintenance section), “0” is set as a reference value that is an intermediate value of the standard allowable range, and two standard lines 36 indicating the upper limit value and the lower limit value of the allowable error range are displayed. In the Step B section, the transmission timing of the mobile terminal 20 to be measured does not deviate from the two standard lines 36 and is within the allowable error range of the standard value, so the mobile terminal 20 in the Step B section. Can be determined to be normal.

  In the Step C section (delay section), “0” is set as a reference value that is an intermediate value of the standard allowable range, and two standard lines 36 indicating the upper limit value and the lower limit value of the allowable error range are displayed. In the Step C section, the transmission timing of the mobile terminal 20 to be measured does not deviate from the two standard lines 36 and is within the allowable error range of the standard value. Therefore, the mobile terminal 20 in the Step C section. Can be determined to be normal.

  In the StepD section (advanced section), “0” is set as a reference value that is an intermediate value of the standard allowable range, and two standard lines 36 indicating the upper limit value and the lower limit value of the allowable error range are displayed. In the section of StepD, it can be seen that the transmission timing of the mobile terminal 20 to be measured exceeds the upper limit value of the standard value, and an abnormality has occurred in the transmission timing. Accordingly, it can be determined that the transmission timing of the mobile terminal 20 in Step D is abnormal. Further, the error value graph display area 34 is displayed so as to be identifiable, for example, by color-coded display or blinking display, with the transmission timing disturbance as point e.

The display example shown in FIG. 9 shows the deviation between the deviation amount graph display area 33 described in FIG. 7 and the previous slot adjacent in time series so as to correspond to this deviation amount graph display area 33. This is an example in which a difference graph display area 35 in which the amount differences are arranged is displayed. The shift amount graph display area 33 is the same as that described with reference to FIG.
Thus, calculating the deviation amount difference is equivalent to differentiating the original value. Therefore, by calculating the difference and displaying the graph, it is possible to easily find the changing point of the original graph.

  In addition, the standard line 36 is displayed at Step B, Step C, and Step D in the deviation amount graph display area 33, and the point where the transmission timing is disturbed is displayed as an identifiable point such as color-coded display or blinking display, and a difference graph The display area 35 displays the position corresponding to the point f as the point g, and the transmission timing disturbance is identifiable in the same manner as the point f.

Next, the processing operation of the signal measuring apparatus 1 having the above configuration will be described with reference to FIG. Here, similarly to the specification of the measurement method used in the above display example, the transmission timing is measured by proceeding in the order of the feedback section, the maintenance section, the delay section, the advance section, and the undefined section.
As a premise of the following processing operation, a state where communication is established between the signal measuring apparatus 1 and the mobile terminal 20, that is, to which time slot the uplink and downlink of the mobile terminal 20 are assigned. Needless to say, it is in a state where it is determined.

First, a signal is received from the mobile terminal 20 to be measured, and the transmission timing of the time slot to which the mobile terminal 20 is assigned is extracted from the received data of this signal (ST1). Next, the number of transmission timing controls of the mobile terminal 20 to be measured is set by setting a measurement method for measuring the transmission timing of the mobile terminal 20 (ST2).
In ST2, since the measurement method is set, the number of times of transmission timing control is set, and the processing procedure (in this example, the processing is performed in the order of the feedback section, the maintenance section, the delay section, the advance section, and the undefined section. Perform) is also set.

  When the number of transmission timing controls is set in ST2, control is performed to match the transmission timing of the mobile terminal 20 with the reference timing (ST3). Then, in accordance with the set transmission timing control count, control is performed to maintain the transmission timing of the mobile terminal 20 (SSbit = 01 SS command is transmitted to the mobile terminal 20) (ST4), and the set control count is executed. It is determined whether or not (ST5).

In ST5, when the number of times that the transmission timing is controlled to the reference timing is executed for the set number of times of control (ST5-Yes), next, the control for delaying the transmission timing of the mobile terminal 20 by 1/8 chip (SSbit) = SS command of = 00 is transmitted to the mobile terminal 20) (ST6), and it is determined whether or not the set number of times of control has been executed (ST7).
On the other hand, when the number of times that the transmission timing is controlled to the reference timing is not executed for the set number of times of control (ST5-No), the process returns to ST4 again to perform control to maintain the transmission timing of the mobile terminal 20 .

In ST7, when the number of times the transmission timing is controlled in the delay direction is executed by the set number of times of control (ST7-Yes), next, the control for advancing the transmission timing of the mobile terminal 20 by 1/8 chip ( SSbit = 11 SS command is transmitted to the mobile terminal 20) (ST8), and it is determined whether the set number of times of control has been executed (ST9).
On the other hand, when the number of times of controlling the transmission timing in the delay direction has not been executed for the set number of times of control (ST7-No), the process returns to ST6 again to control the transmission timing of the mobile terminal 20 to be delayed.

In ST9, when the number of times that the transmission timing is controlled in the forward direction is executed for the set number of times of control (ST7-Yes), next, control for making SScommand undefined (for example, SSbit = undefined) 10 SS command is transmitted) (ST10), and it is determined whether or not the set number of times of control has been executed (ST11).
On the other hand, when the number of times of controlling the transmission timing in the advance direction is not executed for the set number of times of control (ST9-No), the process returns to ST8 again to perform control to advance the transmission timing of the mobile terminal 20. .

In ST11, when the number of times that SScommand is undefined is executed for the set number of times of control (ST11-Yes), the measurement results so far are stored in the measurement result storage means 16c (ST12). Based on the measured result and the set number of time slot intervals, the shift amount of the time slot is calculated (ST13). Based on the various setting contents from the setting operation unit 11, the display control unit 18 creates display data relating to the display contents, and then displays them on the display unit 19 (ST14).
On the other hand, when the number of times that SScommand is undefined has not been executed for the set number of times of control (ST11-No), control returns to ST10 again and SScommand is undefined.

As described above, the signal measuring apparatus 1 described above sets the transmission timing from the mobile terminal 20 so that the transmission timing from the mobile terminal 20 to be measured matches the reference timing based on the specifications of the measurement method set in advance. A timing control command for delaying or a command for transmitting a timing control command for advancing the transmission timing from the mobile terminal 20, a timing control command for maintaining the transmission timing, a timing control command for delaying the transmission timing, and advancing the transmission timing A timing control command and a timing control command for undefining SS command for controlling transmission timing are sequentially transmitted to the mobile terminal 20 by the set number of times of control. Then, the transmission timing is calculated by extracting the transmission timing of a specific time slot to which the mobile terminal 20 to be measured is allocated from the signals transmitted from the mobile terminal 20 in response to each transmitted command. Then, the deviation amount is calculated from the calculated transmission timing, and the transmission timing of the mobile terminal 20 is determined to be good or bad by comparing with a preset standard value.
Therefore, it is possible to easily perform measurement related to synchronization of transmission timing important for the mobile terminal 20 adopting a time division / synchronization / code division multiplexing method such as TD-SCDMA as a communication method and easily grasp the measurement result. Can do.

  Further, when displaying the measurement results on the display unit 19, the measured transmission timings are displayed side by side continuously in time series, and the measured transmission timing deviation amount and an error value based on the deviation amount are obtained. Since the displayed graph can be displayed in a predetermined display area, the operator can easily observe the transmission timing of the mobile terminal 20 as the measurement target.

  Further, since the standard line 36 obtained from the standard value set in advance is displayed in the graph displayed on the display unit 19, the operator can easily determine whether the transmission timing is normal or abnormal in the graph. be able to. Further, when an abnormality occurs in the transmission timing, the corresponding part is displayed so as to be identifiable, for example, by color-coded display or blinking display, so that the operator can further reliably identify the abnormal part.

  Moreover, since the deviation amount is calculated according to the set number of time slot intervals, the desired measurement of the operator can be performed by arbitrarily setting the number of slot intervals when calculating the deviation amount. .

  By the way, in the above-mentioned form, as a specification of the measurement method for controlling the transmission timing of the mobile terminal, Step A (feedback section) for performing control to match the current transmission timing of the mobile terminal 20 to be measured with the reference timing, transmission Step B (maintenance section) that performs control to maintain timing, Step C (delay section) that performs control to delay the transmission timing a predetermined number of times in the delay direction, and Step D (advance section) that performs control to advance the transmission timing by a predetermined number of times in the advance direction As described in the example in which processing is performed in order, if the configuration includes at least each step of the delay interval, the advance interval, and measures the transmission timing of the signal transmitted from the mobile terminal based on the command corresponding to each interval, In particular, the procedure of each step is not limited.

  In addition, as a control method of transmission timing in the delay interval, the advance interval, the maintenance interval, and the undefined interval, the timing control command (SScommand) is continuously performed for the number of times set in advance for the mobile terminal 20 to be measured. The transmission structure has been described (in the display examples shown in FIGS. 6 to 9, the number of times of control is set to 6). For example, the degree of change (or maintenance) within an arbitrarily set control time is set in advance. Thus, the transmission timing can be measured in the same manner as the control method based on the number of times described above.

Further, the slot extraction unit 16a extracts only the reception data of a specific time slot from the reception data stored in the data storage unit 15c. For example, when the reception data of all the time slots is measured, This process can be omitted.
At this time, when only the received data of a specific time slot is displayed on the display unit 19 among all the received data, the time slot to be displayed is first specified by the setting operation unit 11, and the specified time is displayed. Only the received data of the slot is extracted from the measurement result storage means 16c. Then, in the slot timing calculation means 16b, a deviation amount, an error value, a difference between the deviation amounts and the like based on the received data of the extracted time slot are measured and stored again in the measurement result storage means 16c. By creating the display data, only the display content of a specific time slot can be displayed on the display unit 19.

  The slot timing calculation unit 16b performs various processes based on the transmission timing obtained from the reception data at the specific slot timing detected by the slot extraction unit 16a. For example, no specific time slot is set in advance. If the setting of the number of time slot intervals is changed during measurement or when a specific time slot or the number of intervals is set, the corresponding received data is received from the received data stored in the measurement result storage means 16c. Various processes such as transmission timing and deviation amount calculation can also be performed.

DESCRIPTION OF SYMBOLS 1 Signal measuring device 11 Setting operation part 12 Control part 13 Transmission part 13a Timing control request means 13b Transmission circuit 14 Directional coupler 15 Reception part 15a Reception circuit 15b A / D converter 15c Data storage means 16 Measurement part 16a Slot extraction means 16b Slot timing calculation means 16c Measurement result storage means 17 Determination section 18 Display control section 19 Display section 20 Mobile terminal 31 Transmission timing graph display area 32 Section display area 33 Deviation amount graph display area 34 Error value graph display area 35 Difference graph Display area 36 Standard line

Claims (8)

A signal measuring device (1) that communicates with a mobile terminal (20) to be measured by time division / synchronization / code division multiplexing, and measures a signal from the mobile terminal,
A transmission unit (13) for continuously transmitting a timing control command for controlling transmission timing of the mobile terminal to the mobile terminal a plurality of times;
The transmission timing of the signal transmitted from the mobile terminal according to the timing control command is measured, and the time slot to which the mobile terminal is assigned from the signal from the mobile terminal and a predetermined time slot from the time slot measuring unit for calculating a difference between the transmission timing of the number of intervals apart time slots as the offset of the transmission timing between timeslots (16),
A display unit (19) for displaying a measurement result measured by the measurement unit;
A display control unit (18) for displaying the amount of transmission timing shift between the time slots calculated by the measurement unit in a time series and displaying the graph on the display unit;
A signal measuring device comprising: A setting operation unit (11) for setting the number of intervals is provided, and the measurement unit (16) calculates the deviation amount according to the number of intervals set by the setting operation unit. The signal measuring device according to claim 1. It said measuring unit (16) calculates an error value by subtracting the reference value is an intermediate value of the tolerance range of the offset of either RaTadashi rated value of the transmission timing between the calculated time slot,
The said display control part (18) arranges the said error value calculated in the said measurement part continuously in time series, and displays it on the said display part (19) as a graph, The display part (19) characterized by the above-mentioned. Signal measuring device. When the measurement unit (16) displays the calculated deviation amount in time series, for each of the arranged deviation amounts, calculate a difference from the adjacent previous deviation amount,
The said display control part (18) arranges the difference of the deviation | shift amount calculated in the said measurement part continuously in time series, and displays it on the said display part (19) as a graph, It is characterized by the above-mentioned. The signal measuring device according to any one of the above. The timing control command to be transmitted to the mobile terminal (20) includes at least a timing control command for delaying transmission timing from the mobile terminal and a timing control command for advancing transmission timing from the mobile terminal,
The transmission timing of the signal transmitted from the mobile terminal corresponding to each timing control command measured by the measurement unit (16) is compared with the standard value corresponding to each command, and the transmission timing is compared. 5. The signal measuring apparatus according to claim 1, further comprising: a determination unit that determines whether or not a value falls within an allowable error range of the standard value. The display control unit (18) includes a standard line obtained from the standard value for determining whether the deviation amount or the error value calculated by the measurement unit (16) is normal or abnormal, 6. The signal measuring apparatus according to claim 5, wherein the signal measuring apparatus is displayed so as to overlap the graph. The transmission timing determined to be normal and the transmission timing determined to be abnormal based on the determination result of whether or not the transmission timing determined by the determination unit (17) is within the allowable error range of the standard value. The signal measuring device according to claim 5 or 6, wherein the signal is displayed so as to be identifiable in the graph. A signal measurement method for communicating with a mobile terminal (20) to be measured by time division / synchronization / code division multiplexing and measuring a signal from the mobile terminal,
Transmitting a timing control command for delaying the transmission timing from the mobile terminal or a timing control command for advancing the transmission timing to the mobile terminal, and matching the transmission timing from the mobile terminal with a reference timing When,
Transmitting a timing control command for maintaining the transmission timing from the mobile terminal to the mobile terminal continuously several times;
Transmitting a timing control command for delaying the transmission timing from the mobile terminal to the mobile terminal continuously several times;
Transmitting a timing control command for advancing the transmission timing from the mobile terminal to the mobile terminal a plurality of times in succession;
Receiving a signal transmitted from the mobile terminal in response to each command;
Measuring the transmission timing of the received signal;
Determining whether the measured transmission timing falls within the allowable error range of the set regulations rated value,
Shift amount of the transmission timing between the from the signal from the mobile station and the mobile station is allocated a time slot, the time slot data the difference between the transmission timing of the predetermined number of intervals apart time slots from time slot As a step of calculating as
And displaying graph shift amount of the transmission timing between the calculated issued said time slots in a time-series continuity side by side display unit (19),
A signal measurement method comprising:

Images