JP3854470B2 - Radio service area evaluation equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides a radio service area evaluation for evaluating a radio service area of each base station in a mobile communication network system such as a mobile phone adopting a W-CDMA (wideband-code division multiple access) system. Relates to the device.
In particular, the present invention relates to a radio service area evaluation apparatus that performs high-speed measurement by using a plurality of radio service area evaluation apparatuses and allocating a plurality of measurement signals to each apparatus.
[0002]
[Prior art]
In a mobile network system such as a mobile phone, a large number of base stations are installed close to each other in a telephone service area. In this case, a part of each cell indicating a range in which radio waves of base stations adjacent to each other reach is partially overlapped. By overlapping adjacent cells in this way, even if the mobile station moves to another cell while making a call, the base station of the communication destination is automatically switched and the call is not blocked.
[0003]
Therefore, in order to provide a good call service to the owner of the mobile phone, not only the general radio wave valley where both radio waves do not reach between each base station, but also the shadow of the building, etc. There is a need to eliminate local radio wave valleys.
[0004]
Therefore, at each point in the telephone service area, not only the radio wave from one or a plurality of base stations having the corresponding point as a cell but also the radio wave from the base station of the adjacent cell is measured, Evaluating is very important for newly installing a base station or maintaining an installed base station.
[0005]
When measuring the radio wave condition at each point in the telephone service area, as shown in FIG. 6, the measurer installs the measuring device 1 in the measurement vehicle 200 and has a plurality of base stations 300 installed therein. Move in. Then, the radio wave 400 from each base station 300 is received at each point while moving, the received signal level of each radio wave 400 is measured, and each radio wave state at the corresponding point is evaluated.
[0006]
A radio wave 400 transmitted from each base station 300 to each mobile station (not shown) includes a W-CDMA signal. In this W-CDMA signal, a common pilot channel (CPICH), a synchronization channel (SCH), and a plurality of data channels (CH1 to CHN) spread with different codes are combined in one frequency band. Included in state.
[0007]
As shown in FIG. 7, the common pilot channel (CPICH) is spread by a code (for example, a PN code) generated by a 9-bit primary code and a 4-bit secondary code that specify a base station.
[0008]
Further, the 9-bit primary code is composed of a 6-bit group code and a 3-bit cell code. Therefore, since each base station 300 is specified by 9 bits, 2⁹= One channel (CH) code among the 512 codes is assigned to each base station 300. The radio wave service area evaluation apparatus 1 mounted on the measurement vehicle 200 measures the reception signal levels of 512 types of base stations.
[0009]
[Problems to be solved by the invention]
However, as shown in FIG. 6, in the radio wave service area evaluation apparatus 1 that evaluates the radio wave state of the radio wave 400 transmitted from each base station at each point in the radio wave service area, the following problems that should still be improved was there.
[0010]
In order to measure the reception levels of a plurality of base stations at high speed, a plurality of radio wave service area evaluation apparatuses 1 are required. However, since the radio wave service area evaluation apparatus 1 is mounted on the measurement vehicle 200, it is difficult to simultaneously press a plurality of switches such as start of measurement. Furthermore, even if a plurality of units are controlled, a controller is required, and the number of measuring instruments that can be measured simultaneously is determined by the number of input terminals of the controller.
[0011]
The present invention has been made in view of such circumstances, and is a device for realizing speedup of repeated measurement by connecting a plurality of devices in a daisy chain and synchronizing them, and transferring information to a lower device. Can be done with one control signal.
[0012]
[Means for Solving the Problems]
In order to solve the above problems, the first invention receives a W-CDMA signal transmitted from a plurality of base stations to each mobile station and sets a received signal level according to a timing signal indicating a measurement timing. A radio service area evaluation apparatus that measures and evaluates the radio service area of each base station based on the received signal level, wherein the timing signal is a measurement capture timing signal that captures a W-CDMA signal, measurement start information, and measurement It is a master synchronization signal including an evaluation target section signal indicating end information, or includes a predetermined information code including measurement start information, measurement end information, and measurement capture timing for capturing a W-CDMA signal, and is composed of a pulse group When the timing signal that is the master synchronization signal is input, the radio signal support is performed. When the service area evaluation device is set as a master and the timing signal that is the slave synchronization signal is input, a switching unit for setting the radio service area evaluation device as a slave, and the radio service area is evaluated according to the timing signal When the measurement unit and the radio wave service area evaluation device are set as a master by the switching unit, the master synchronization signal is sent to the measurement unit and converted into a slave synchronization signal and output to the outside. When the radio service area evaluation device is set as a slave by the switching unit, the conversion unit that outputs the slave synchronization signal to the outside as it is, and the radio service area evaluation device is set as a slave by the switching unit. If the slave synchronization signal output as it is from the conversion unit, A decoding unit that reproduces measurement start information, measurement end information, and measurement capture timing included in a predetermined information code and sends them to the measurement unit, and the radio wave service area evaluation device is set as a slave by the switching unit Comprises a gate generation unit for generating a gate signal for counting pulses included in the predetermined information code within a predetermined time range from the slave synchronization signal output as it is from the conversion unit.
[0013]
In addition, the second invention selects a plurality of base stations, receives a W-CDMA signal for mobile stations transmitted from the base station, a start signal indicating a measurement start time, and a trigger signal indicating a data acquisition time , And a radio wave service area evaluation apparatus comprising a measuring unit for measuring radio wave service areas of the base stations based on the measured level based on an end signal indicating a measurement end time. Since one of the service area evaluation apparatuses sends measurement timing information to the other and performs measurement at the measurement timing, if it corresponds to a radio wave service area evaluation apparatus that first receives a W-CDMA signal, A switching unit for switching to a slave when corresponding to a service area evaluation device, and the opening when the switching unit is set as a master. The signal is converted into a first predetermined number of pulse groups, the trigger signal is converted into a second predetermined number of pulse groups, and the signal indicating the end time is converted into a third predetermined number of pulse groups, and the measurement timing of the temporary series is converted. Information can be sent to a radio service area evaluation device set as a slave, and when the switching unit is set as a slave, the measurement timing information is received from a higher radio service area evaluation device and When the conversion unit for enabling output to the radio wave service area evaluation device and the switching unit are set as slaves, the first predetermined number of pulse groups, the second predetermined number from the timing information of the temporary sequence In order to separate a plurality of pulse groups and a third predetermined number of pulse groups, a gate generation unit for generating a gate signal having a window time corresponding to the pulse group, and the switching unit If the signal is set to, a decoding start signal, a decoding trigger signal, and a decoding end signal are generated by counting the number of pulses within each window time of the gate signal generated from the gate generation unit, A decoding unit for sending to the measurement unit for measurement instead of the start signal, trigger signal, and end signal.
[0014]
In addition to the radio wave service area evaluation apparatus of the second invention, the third invention receives the start signal, the trigger signal, and the end signal from the outside when set as a master by the switching unit. Features.
[0015]
In addition, in the fourth aspect of the invention, in addition to the radio wave service area evaluation device of the second or third aspect of the invention, the gate generation unit and the decoding unit operate when the switching unit sets the master, and the measurement unit , And operates with a decoding start signal, a decoding trigger signal, and a decoding end signal from the decoding unit.
[0016]
The fifth invention is directed to a mobile station that selects a plurality of base stations and is transmitted from the base stations. W − CDMA A radio service area evaluation apparatus comprising a measurement unit for receiving a signal and evaluating the radio service area of each base station based on a level of the received signal, wherein one of the radio service area evaluation apparatuses Since it sends measurement timing information to the other side and measures at the measurement timing, it becomes a master when it corresponds to a radio service area evaluation device that first receives a W-CDMA signal, and corresponds to other radio service area evaluation devices A switching unit for becoming a slave, a switching unit for becoming a slave if applicable to other radio wave service area evaluation devices, and a first unit for connecting to the master side 1 And the terminal to be connected to the slave side 2 A series of terminals, a first predetermined number of pulse groups indicating the measurement start time, a second predetermined number of pulse groups indicating the data acquisition time, and a third predetermined number of pulse groups indicating the measurement end time. In the case where the master is set according to an instruction from the code generator and the switching unit generated as a series signal, the output of the code generator is 2 A switch unit that sends a signal from the first terminal to the second terminal, the first predetermined number of pulse groups, and the second predetermined number of To separate a pulse group and a third predetermined number of pulse groups, count the number of pulses in each pulse group, decode the measurement start, trigger signal, and measurement end, and send them to the measurement unit for measurement. The decoding timing generation unit is provided.
[0017]
According to a sixth aspect of the present invention, in the radio service area evaluation apparatus according to the first, second, third, fourth, or fifth aspect, a plurality of radio service area evaluation apparatuses are connected to thereby evaluate one radio service area. A device is set as a master by the switching unit of the device, and another radio service area evaluation device is set as a slave by the switching unit of the device, and each radio wave service area evaluation device shares the measurement of the received signal level. It is characterized by being able to.
[0018]
In the radio wave service area evaluation apparatus configured as described above, the top one radio wave service area evaluation apparatus in which a plurality of radio wave service areas are connected in series is set as a master, and the other is set as a slave. The master device receives, as a measurement timing signal, a master synchronization signal including a measurement capture timing signal (a1) for capturing a W-CDMA signal and an evaluation target section signal (a2) indicating measurement start information and measurement end information. And a group of pulses including a predetermined information code including a measurement acquisition timing for acquiring a master synchronization signal, measurement start information, measurement end information, and a W-CDMA signal. Is converted to a slave synchronization signal composed of the following and sent to a slave device connected to the subsequent stage.
[0019]
The slave device evaluates the radio wave service area of its own channel according to the timing of the slave synchronization signal, and sends the slave synchronization signal as it is to the slave device connected to the subsequent stage.
[0020]
In the radio wave service area evaluation apparatus configured as described above, when one radio wave service area evaluation apparatus is set as a master, the reception signal level can be measured while walking by carrying one of the radio wave service area evaluation apparatuses. Further, by connecting a plurality of radio service area evaluation apparatuses to each radio service area evaluation apparatus 1 in which a plurality of measurement objects are connected in series, the number of measurement objects per unit is reduced. As a result, 1 The measurement time can be shortened and repeated measurement can be made faster. As a result, the measurement results of the plurality of radio wave service area evaluation apparatuses 1 are processed by another processing apparatus and displayed as signal levels at the corresponding points. Therefore, the measurer can easily compare and contrast the state of each radio wave 400 from each base station 300.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In order to understand the present invention, the use example of the present invention shown in FIG. 2 will be described. In FIG. 2, n radio wave service area measuring devices (hereinafter referred to as “devices”) 1 are arranged, the first device is set to the master state, all other devices are set to the slave state, and each device measures. For example, it is assumed that the channels that are in charge are set to handle 10 different channels.
[0022]
In such a state, the master device receives external synchronization signals (measurement start / measurement end / trigger) a1 and a2 and measures its own channel and slave synchronization for causing the slave device to perform measurement in synchronization. A signal b is generated and output. Each slave device receives the same slave signal b and performs measurement of each channel it handles.
[0023]
In the present invention, a single device can be a master and a slave, and synchronization between the master device and the slave device can be easily made easy, so that multi-channel measurement can be performed quickly. .
[0024]
(First embodiment)
In the following, based on the configuration example of the apparatus of the present invention shown in FIG. 1, the apparatus according to the present invention will be described separately for the case of operating in the master state and the case of operating in the slave state.
[0025]
(1) When operating in the master state
In this case, the switches 21a, 21b, and 60 are set to the M side (master side) by the switching unit 72 in the panel 70. Therefore, when operating as a master, the decoding unit 30 and the gate generation unit 40 do not perform substantial operations, and this will be described in the operation as a slave described later.
[0026]
In FIG. 1, first, the synchronization selection unit 71 selects whether to operate with the external synchronization signal a (a 1, a 2) or with the signal from the internal synchronization signal generation unit 50. As shown in FIG. 3, the external synchronization signal a is generated from an external trigger signal a1 indicating timing when the measurement unit 80 acquires data, and a start / stop signal a2 including timing information of measurement start and end. Become. The output signal of the synchronization signal generator 50 is substantially the same as the external synchronization signal a.
[0027]
The measuring unit 80 receives the trigger signal a1 within the period determined by the start / stop signal a2 obtained through the switches 21a and 60, and is equivalent to the number of channels set by the channel selecting unit 73 (10 channels in FIG. 2). Measure.
[0028]
On the other hand, the code conversion unit 22 included in the conversion unit 20 receives the start / stop signal a2 as shown in the timing chart of FIG. 1 pulse group), the timing at the time of stop is code-converted into three pulse groups (third pulse group) with a fixed period T, and one pulse (first pulse) with a fixed period T is received in response to a trigger signal. 2), and outputs them as a series of time-series slave synchronization signals b. The slave synchronization signal b is sent to the device 1 set to the lower slave state.
[0029]
(2) When operating in the slave state
In this case, the switches 21a, 21b, 60 are set to the S side (slave side) by the switching unit 72 in the panel 70. Therefore, the code conversion unit 22 does not operate when operating as a slave. The conversion unit 20 receives the slave synchronization signal b from the upper master device 1 and outputs the slave synchronization signal b (see FIG. 2).
[0030]
The gate generation unit 40 of the slave device 1 that has received the slave synchronization signal b from the host device 1 generates a gate signal c (see FIG. 4) having a predetermined window time based on the slave synchronization signal b.
[0031]
This predetermined window time is designed to be from the time of receiving the slave synchronization signal b and receiving the first pulse that arrived after the lack of a pulse of a pulse having a constant period T to the time when a pulse group is included. ing. That is, the window time is set such that each pulse group can be separated with a time when a pulse with a constant period T is missing.
[0032]
The counter 31 receives the slave synchronization signal b and the gate signal c, separates each pulse group, and counts the number of pulses for each pulse group (see d in FIG. 4). Therefore, after counting a certain group of pulses, the count is cleared, and when the next group of pulses comes, the counting starts from the beginning. For example, after counting two pulses, the information decoding unit 32 generates a decoding start signal (e2 in FIG. 4), and after counting one pulse, the information decoding unit 32 generates a decoding trigger signal ( After generating e1) of FIG. 4 and counting the three pulses, a decoding stop signal (e2 of FIG. 4) is generated and sent to the measuring unit 80 to be measured at these timings.
[0033]
(Second embodiment)
In the first embodiment, when the apparatus 1 performs the master operation, the decoding unit 30 and the gate generation unit 40 do not operate in the first embodiment. 80 is configured to operate with a decoding start signal, a decoding trigger signal, and a decoding end signal from the decoding unit 30 both in the master operation and in the slave operation. In this way, the master device and the slave device can measure at the same time. Specifically, in FIG. 1, the switch 60 may be eliminated and the output of the information decoding unit 32 may be directly input to the measurement unit 80.
[0034]
(Third embodiment)
FIG. 5 shows a configuration corresponding to claim 5 in the third embodiment, and the same reference numerals in FIG. 1 as those in FIG. 1 indicate the same functions. In the present invention, as shown in FIG. 5, the first terminal 90a is connected to the upper master device, and the second terminal 90b is connected to the lower slave device. When the corresponding device becomes the master, the switch unit 100 is set to M (master side), the code generation unit 110 generates the slave synchronization signal b, and sends it to the slave side via the second terminal 90b. In the case of a slave, the slave synchronization signal b from the upper master device is received by the first terminal 90a and sent as it is to the lower slave side via the second terminal 90b.
[0035]
The code generator 110 is a combination of the function of the synchronization signal generator 50 of FIG. 1 and the function of the code converter 22. Further, the synchronization signal generator 50 may be configured to receive a synchronization signal from the outside.
[0036]
(Explanation of operation of radio wave service area evaluation equipment)
FIG. 6 is a schematic diagram showing a state of radio waves using the radio service area evaluation apparatus 1 according to the embodiment. The measurer mounts the radio wave service area evaluation apparatus 1 according to the embodiment of the present invention on the measurement vehicle 200 and moves within a telephone service area where a plurality of base stations 300 are installed. Then, the radio wave 4 from each base station 300 is received at each point while moving, the reception signal level of each radio wave 4 is measured, and each radio wave state at the corresponding point is evaluated.
[0037]
As described above, the radio wave 400 transmitted from each base station 300 to each mobile station (not shown) includes a W-CDMA signal. In this W-CDMA signal, a common pilot channel (CPICH) 9, a synchronization channel (SCH) (not shown), and a plurality of data channels (CH1 to CHN) spread with different codes in one frequency band. ) (Not shown) is included in a signal synthesized state. As shown in FIG. 7, the common pilot channel (CPICH) 9 is spread by a code (for example, a PN code) generated by a 9-bit primary code 9a and a 4-bit secondary code 9b that specify a base station.
[0038]
Further, the 9-bit primary code 9a is composed of a 6-bit group code and a 3-bit cell code. Therefore, since each base station 300 is specified by 9 bits, 2⁹= One channel (CH) code among the 512 codes is assigned to each base station 300. Since this 9-bit primary code 9a is incorporated into a W-CDMA signal in a state where the spectrum is spread with a PN code, for example, the radio wave service area evaluation apparatus 1 installed in the measurement vehicle 200 prepares 512 types of PN codes in advance. Then, the original common pilot channel (CPICH) 9 is extracted to identify the base station 300 that is the transmission source of the radio wave 400.
[0039]
Although not particularly illustrated, the radio wave service area evaluation apparatus 1 mounted on the measurement vehicle 200 is provided with a display and an operation unit on the front surface of the case. The operation unit includes a measurement start / end button, a scroll (arrow) button, a selection button, a rotary knob, and a plurality of function buttons. Furthermore, a serial port for connecting to an AC adapter connector and an external PC (personal computer) is attached to the side of the case.
[0040]
In the buffer memory in the apparatus, an area for writing the signal level of the corresponding channel calculated by the arithmetic processing unit every 10 ms is formed for each channel (CH) allocated to each of the 512 base stations 300. Yes. This buffer memory is composed of a FIFO memory, and stores, for example, the latest signal levels for 30 minutes. The level calculation unit and N (10 in the description of FIG. 2) data in each of the channels 1 to 32 stored in the signal data memory are statistically processed and written to the level memory. In the level memory, for each channel 1 to 32, the channel (CH) code, Ec (received energy per channel) calculated by the total method, Ec / No (received energy Ec and received power density per channel) No.) and SIR (ratio between signal level and interference signal level) are written.
[0041]
The data extraction unit extracts N unit data of the channel designated by the display format instruction unit from among the 32 channels stored in the signal data memory, and sends the data to the data editing unit.
[0042]
The data editing unit edits each data (signal level) of the N unit data of each channel input from the data extraction unit into a display format (display format) input from the format memory, and displays the display screen of the display unit Is displayed graphically as characteristic data on the upper part of the.
[0043]
Further, the data editing unit displays the above-described channel (CH) code, Ec, Ec / No, and SIR data of each channel 1 to 32 stored in the level memory in the format of the list. Display output on the lower part of the display screen.
[0044]
The list is not displayed all at the same time because of the space on the display screen, but the channel to be displayed can be selected by the measurer operating the scroll keys.
[0045]
Further, the current position of the measurement vehicle 200 obtained from the GPS satellite is displayed on the display screen of the display in the form of latitude and longitude. Also this
[0046]
Furthermore, the display screen of the display unit displays a plurality of function keys such as “level conversion” and “save”, and the measurer can specify any function by specifying the corresponding function button on the operation unit. The key can be selected.
[0047]
For example, when the “Save” function key is designated by the function button of the operation unit, the stored contents of the signal data memory are written into the FD or IC card attached to the FD attachment unit or IC card attachment unit.
[0048]
In addition, at each point in the telephone service area, in addition to the radio wave 400 from the base station 300 having the corresponding point as a cell, a large number of radio waves 400 from each base 300 serving another cell are also received. In that case, as shown in FIG. 2, each base station 300 is allocated to each radio wave service area evaluation apparatus 1, and is transmitted from each base station 300 at each point in the telephone service area to the measurer, for example, with a high signal level. The radio wave state of the radio wave 400 can be reliably evaluated. In this case, FD data written by a plurality of devices is processed by a processing device such as a personal computer to evaluate the radio wave service area.
[0049]
【The invention's effect】
As described above, the radio wave service area evaluation apparatus of the present invention is configured to connect a plurality. Therefore, one radio service area evaluation apparatus can be reduced in size, weight, and power consumption, and a measurer can carry the apparatus, walk behind the alley, and measure data in the radio service area.
[0050]
In addition, with the radio service area evaluation device as described above, it is possible to switch between master and slave functions and to decode and measure timing signals with simple time series signals between master and slaves. By allocating the area evaluation devices to the devices connected in series and measuring, the number of objects to be measured per unit is reduced. As a result, one measurement time is shortened, and repeated measurement can be accelerated. That is, the processing speed according to the vehicle speed can be realized. Furthermore, a large number of received signals existing on a wide road can be measured.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a radio wave service area evaluation apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram showing a usage example in which a plurality of radio wave service area evaluation apparatuses according to an embodiment of the present invention are used.
FIG. 3 is a time chart showing the operation of the master device according to the embodiment;
FIG. 4 is a time chart showing the operation of the slave device according to the embodiment;
FIG. 5 is a block diagram showing a radio wave service area evaluation apparatus according to another embodiment of the present invention.
FIG. 6 is a schematic diagram showing measurement of radio wave conditions using a radio service area evaluation apparatus.
FIG. 7 is a frame configuration diagram of a common pilot channel incorporated in a W-CDMA signal.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Radio wave service area evaluation apparatus, 20 ... Conversion part, 30 ... Decoding part, 40 ... Data generation part, 72 ... Switching part, 80 ... Measurement part, 90a ... First terminal, 90b ... Second terminal, 100 ... Switch unit, 110... Code generation unit, 120... Decoding timing generation unit.

Claims (6)

Receiving W-CDMA signals transmitted from a plurality of base stations to each mobile station, measuring a received signal level in accordance with a timing signal indicating a measurement timing, and each of the base stations based on the received signal level A radio wave service area evaluation apparatus (1) for evaluating radio wave service areas of
The timing signal is a master synchronization signal including a measurement capture timing signal (a1) for capturing a W-CDMA signal and an evaluation target section signal (a2) indicating measurement start information and measurement end information, or measurement start information and measurement It is a slave synchronization signal including a predetermined information code consisting of end information and a measurement capturing timing for capturing a W-CDMA signal, and configured by a pulse group,
Set master the radio wave coverage area evaluation unit when entering a timing signal which is the master synchronization signal, switching for setting the radio wave coverage evaluation device to the slave when the inputs a timing signal which is the slave synchronization signals Part (72);
A measurement unit (80) for evaluating a radio wave service area according to the timing signal;
When the radio wave service area evaluation device is set as a master by the switching unit,
The master synchronization signal is sent to the measurement unit, converted into a slave synchronization signal and output to the outside, and when the radio wave service area evaluation device is set as a slave by the switching unit, the slave synchronization signal is A conversion unit (20) that outputs to the outside as it is,
When the radio service area evaluation device is set as a slave by the switching unit, measurement start information, measurement end information, and measurement included in the predetermined information code from the slave synchronization signal output as it is from the conversion unit A decoding unit (30) for reproducing the capture timing and sending it to the measurement unit ;
When the radio service area evaluation device is set as a slave by the switching unit, the pulses included in the predetermined information code within a predetermined time range are counted from the slave synchronization signal output as it is from the conversion unit. the radio service area evaluation apparatus having the gate generator (40), the generating the gate signals for. Select a plurality of base stations, receive a W-CDMA signal for mobile stations sent from the base station, start signal indicating measurement start time, trigger signal indicating data acquisition time, and end indicating measurement end time A radio wave service area evaluation apparatus (1) comprising a measurement unit (80) for measuring radio signals based on the measured level and evaluating radio wave service areas of the respective base stations, the plurality of radio wave service areas Since one of the evaluation devices sends measurement timing information to the other and performs measurement at the measurement timing, if it corresponds to a radio service area evaluation device that first receives a W-CDMA signal , it is designated as a master and other radio service areas switching unit for switching the slave if applicable to the evaluation unit (72), when the switching unit is set to the master, the start signal Is converted into a first predetermined number of pulse groups, the trigger signal is converted into a second predetermined number of pulse groups, and a signal indicating an end time is converted into a third predetermined number of pulse groups to temporarily measure the measurement timing information. Can be sent to a lower radio service area evaluation device set as a slave, and when the switching unit is set as a slave, the measurement timing information is received from a higher radio service area evaluation device and the lower When the conversion unit (20) for enabling output to the radio wave service area evaluation apparatus and the switching unit are set as slaves, a first predetermined number of pulse groups from the timing information of the temporary sequence, second to separate a predetermined number of pulse groups and the third predetermined number of pulse groups, the gate generator (4 for generating a gate signal having a window time corresponding to the pulse group ) And, when the switching unit is set in the slave decoding start signal by counting the number of pulses in each window time of the gate signal generated from the gate generator, it decodes the trigger signal and the decoding end signal And a decoding unit (30) for sending these signals to the measurement unit for measurement instead of the start signal, trigger signal, and end signal.  3. The radio wave service area evaluation apparatus according to claim 2, wherein the start signal, the trigger signal, and the end signal are received from the outside when the switching unit sets the master.  The gate generation unit and the decoding unit operate when set as a master by the switching unit, and the measurement unit operates with a decoding start signal, a decoding trigger signal, and a decoding end signal from the decoding unit. The radio wave service area measuring apparatus according to claim 2 or 3. A measuring unit (selecting a plurality of base stations, receiving a W-CDMA signal for mobile stations transmitted from the base station, and evaluating the radio service area of each base station based on the level of the received signal) a radio coverage area evaluation device equipped with a 80) (1), since the one among the plurality of the radio service area evaluation device is measured at the measurement timing send measurement timing information to the other, the W-CDMA signal When it corresponds to the radio service area evaluation device to be received first , it becomes the master, and when it corresponds to other radio service area evaluation devices, it becomes the slave and the switching unit (72) for connecting to the master side. 1 terminal (90a), a second terminal (90b) to be connected to the slave side, a first predetermined number of pulses indicating the measurement start time, and a data acquisition time A code generation unit (110) that generates a second predetermined number of pulse groups and a third predetermined number of pulse groups indicating a measurement end time as a series of time-series signals, and an instruction from the switching unit, If set, the output of the code generator is sent to the second terminal, and if set to a slave, the switch ( 160 ) sends the signal from the first terminal to the second terminal . And separating the first predetermined number of pulse groups, the second predetermined number of pulse groups, and the third predetermined number of pulse groups, and starting measurement by counting the number of pulses of each pulse group, A radio wave service area measuring apparatus comprising: a decoding timing generation unit (120) for decoding a trigger signal and measurement end and sending the measurement signal to the measurement unit for measurement. The electrostatic wave coverage evaluation device, by multiple connecting it, radio service area evaluation system one is set to the master by the switching portion of the device, switching of the other radio service area evaluation unit that device 6. The radio wave service area evaluation apparatus according to claim 1, wherein the radio wave service area evaluation apparatus is set as a slave by each unit, and the reception signal level measurement can be shared by the respective radio wave service area evaluation apparatuses.

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