JP2002261682A - Electric wave service area evaluating apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure a reception level of a plurality of base stations with a plurality of apparatuses which are mounted on a measuring vehicle and need a controller for controlling the plurality of apparatuses. SOLUTION: One of a plurality of apparatuses 1 is set as a master unit, and others are set as slave units. The master unit receives a measurement start/measurement completion signal a1 by an operator for conversion to a code of measurement start information and measurement completion information at a converting unit 20, and transmits the information code b to the slave units. Further, after starting measurement, a trigger signal a2 for synchronizing the measurement is carried on an information code b and is transmitted to the slave units. A slave unit transmits a signal received from the master unit as it is to another slave unit connected therewith. A decoding unit 30 decodes the information code b and operates in accordance with the contents of the code. Information decoding generates a gate c after detecting at first a changing point at a gate generating unit 40 to generate a gate c and to count the number of pulses during the time at a counter 31.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a W-CDMA (Wideband-Code Division Multiple Access).
The present invention relates to a radio service area evaluation device that evaluates a radio service area of each base station in a mobile communication network system such as a mobile phone that employs an e access method. In particular, the present invention relates to a radio wave service area evaluation device that performs high-speed measurement by allocating a plurality of measurement signals to each device using a plurality of radio wave service area evaluation devices.

[0002]

2. Description of the Related Art In a mobile network system such as a cellular phone, a number of base stations are installed close to each other in a telephone service area. In this case, each cell indicating the range of radio waves of adjacent base stations partially overlaps with each other. 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 interrupted.

[0003] Therefore, in order to provide a good telephone service to the owner of a mobile phone, it is necessary not only to eliminate a valley of general radio waves where both radio waves do not reach each other between base stations, but also to improve the building. It is necessary to eliminate local valleys of radio waves in the shadows of clouds.

Accordingly, at each point in the telephone service area, not only radio waves from one or a plurality of base stations having the corresponding point as a cell but also radio waves from base stations in adjacent cells are measured, and the corresponding point is measured. Evaluating the radio wave condition is very important for installing a new base station or for maintaining the installed base station.

When measuring the radio wave condition at each point in the telephone service area, as shown in FIG. 6, a measurer mounts the measuring device 1 on a measuring vehicle 200 and sets a plurality of base stations 30.
Move within the telephone service area where 0 is installed. Then, while moving, radio waves 4 from each base station 300 at each point.
00, the received signal level of each radio wave 400 is measured, and each radio wave state at the corresponding point is evaluated.

A radio wave 400 transmitted from each base station 300 to each mobile station of a portable telephone (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 CH) each spread with different codes in one frequency band.
N) is included in a state where the signals are combined.

[0007] 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 specifying a base station, as shown in FIG.

Further, the 9-bit primary code is
It consists of a 6-bit group code and a 3-bit cell code. Therefore, since each base station 300 is specified by 9 bits, 1 out of 2 ⁹ = 512 codes
Number of channel (CH) codes are allocated to each base station 300. The radio wave service area evaluation device 1 mounted on the measurement vehicle 200 measures the received signal levels of 512 types of base stations.

[0009]

However, as shown in FIG. 6, in the radio wave service area evaluation apparatus 1 for evaluating the radio wave condition of the radio wave 400 transmitted from each base station at each point in the radio wave service area, There were the following issues that still need to be improved.

To measure the reception levels of a plurality of base stations at high speed, a plurality of radio service area evaluation apparatuses 1 are required. However, since the radio wave service area evaluation device 1 is mounted on the measurement vehicle 200, it is difficult to simultaneously press switches for starting measurement of a plurality of devices. Furthermore, even if a plurality of units are controlled, a controller is required, and the number of measuring devices that can be simultaneously measured is determined by the number of input terminals of the controller.

The present invention has been made in view of such circumstances, and is an apparatus for daisy-chaining a plurality of apparatuses and synchronizing them to realize high-speed repeated measurement. Can be transmitted by one control signal.

[0012]

Means for Solving the Problems One of a plurality of radio service area evaluation apparatuses 1 is set as a master, and the other is set as a slave. The master device receives the operator's measurement start / measurement end signal, converts the signal into measurement start information and measurement end information codes, and transmits the information code to the slave device.

After the start of the measurement, a trigger signal code for synchronizing the measurement is transmitted to the slave device. The slave device transmits the signal from the master device as it is to the connected slave device. The slave device decodes the information code and operates on the content of the code. In decoding information, a gate is generated since a change point is first detected, and the number of pulses between the gates is defined.

Further, the radio wave service area evaluation apparatus 1 of the present invention has the following configuration. Receiving a W-CDMA signal transmitted to each mobile station from a plurality of base stations and evaluating a radio service area of each base station based on the received signal level; A switching unit (72) for setting the device as a master or a slave; and, when the radio wave service area evaluation device is set as a master by the switching unit, its own measurement start information, measurement end information, and external measurement. A conversion unit that converts the capture timing into a predetermined information code and outputs the same to the outside, or, when the radio wave service area evaluation device is set as a slave by the switching unit, outputs the predetermined information code as it is to the outside. (20)
When the radio wave service area evaluation device is set as a master by the switching unit, it does not function, and when the radio wave service area evaluation device is set as a slave by the switching unit, the predetermined A decoding unit (30) for reproducing measurement start information, measurement end information, and measurement acquisition timing from the information code; and the predetermined information code when the radio wave service area evaluation device is set as a slave by the switching unit. A gate generation unit (40) for generating a gate signal for counting pulses within a predetermined time range from the gate signal;

The radio wave service area evaluation device 1 of the second invention has the following configuration. Select multiple base stations and send W for mobile stations transmitted from that base station.
Receiving a CDMA signal, measuring with a start signal indicating a measurement start time, a trigger signal indicating a data acquisition time, and an end signal indicating a measurement end time, and based on the measured level, a radio service area of each of the base stations. In order to evaluate the above, one of the plurality of radio service area evaluation apparatuses sends measurement timing information to the other to measure at the measurement timing. A switching unit (72) for switching to a slave if the other is true, and a start signal to a first predetermined number of pulse groups and a trigger signal to a A signal indicating the end time is converted into a second predetermined number of pulse groups into a third predetermined number of pulse groups, and operates as a slave as the temporary series of the measurement timing information. Transmission to the radio wave service area evaluation device, and when the switching unit is set as a slave, receives the measurement timing information from the higher radio wave service area evaluation device and passes through the lower radio wave service area evaluation device. A conversion unit (20) for enabling output to the first unit, and when the switching unit is set to a slave, a first predetermined number of pulse groups and a second predetermined number of pulse groups from the temporary sequence timing information. Pulse group and third
A gate generation unit (40) for generating a gate signal having a window time corresponding to the pulse group in order to separate the pulse group into a predetermined number of pulse groups, and the gate generation unit when the switching unit is set as a slave. A decoding start signal, a decoding trigger signal, and a decoding end signal are generated by counting the number of pulses in each window time of the gate signal from the unit, and the measuring unit is replaced with the start signal, the trigger signal, and the end signal. And a decoding unit (30) for sending the data to and measuring it.

The radio wave service area evaluation device 1 of the third invention has the following configuration in addition to the configuration of the second invention. When the master is set by the switching unit, the start signal, the trigger signal, and the end signal are received from outside.

Further, the radio wave service area evaluation device 1 of the fourth invention has the following configuration in addition to the second or third invention. When the master is set by the switching unit, the gate generation unit and the decoding unit operate, and the measurement unit operates with the decoding start signal, the decoding trigger signal, and the decoding end signal from the decoding unit.

Further, the radio wave service area evaluation apparatus 1 of the fifth invention has the following configuration. Select multiple base stations and send W for mobile stations transmitted from that base station.
A measuring unit (80) for receiving a CDMA signal and evaluating a radio service area of each of the base stations based on the level of the received signal, wherein one of the plurality of radio service area evaluation devices is measured by the other; In order to send the timing information and make it measure at the measurement timing, a switching unit (72) for becoming a master when the one corresponds to the above and a slave for the other corresponds to the first unit for connecting to the master side. Terminal (90a), a second terminal (90b) for connection to the slave side, a first predetermined number of pulses indicating the measurement start time, and a second predetermined number of pulses indicating the data acquisition time The third indicating the group and the measurement end time
And a code generator (110) for generating a predetermined number of pulse groups as a series of time-series signals, and an output from the code generator when the master is set by an instruction from the switch. A switch unit (100) for connecting the first terminal and the second terminal when the signal is transmitted to the terminal and set as the slave, the first predetermined number of pulse groups, and the second predetermined number of pulses Group, and a third predetermined number of pulse groups. The number of pulses in each pulse group is counted to decode the start of measurement, the trigger signal, and the end of measurement, and send them to the measurement unit for measurement. A decoding timing generator (120);

Further, in the radio wave service area evaluation apparatus 1 of the fifth invention, by connecting a plurality of the first, second, third, fourth and fifth radio wave service area evaluation apparatuses,
One radio service area evaluation device is set as a master by the switching unit of the device, and the other radio service area evaluation device is set as a slave by the switching unit of the device. Sharing level measurement.

In the radio wave service area evaluation device thus configured, when one radio wave service area evaluation device is set as a master, the reception signal level is measured while walking with one of the radio wave service area evaluation devices. Can be. Further, by connecting a plurality of radio wave service area evaluation devices, a plurality of measurement targets are allocated to each of the radio wave service area evaluation devices 1 connected in series, thereby reducing the number of measurement targets per device. The measurement time of each measurement is shortened, and the repeated measurement can be accelerated. As a result, the measurement results of the plurality of radio service area evaluation devices 1 are processed by another processing device 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]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. For an understanding of the present invention, a description will be given of a use example of the present invention in FIG. In FIG. 2, a radio wave service area measuring device (hereinafter, referred to as “device”) 1 is denoted by n.
It is assumed that the individual devices are arranged, the first device is set to the master state, all the other devices are set to the slave state, and the channels for each device are set to cover, for example, 10 channels different from each other.

In such a state, the master device transmits the external synchronization signals (measurement start / measurement end / trigger) a1 and a2.
And measures a channel assigned to the slave device, and generates and outputs a slave synchronization signal b for synchronizing measurement with a slave device. The devices of the respective slaves receive the same slave signal b and measure the respective channels.

According to the present invention, one device can be a master and a slave, and synchronization between the master device and the slave device can be easily and easily achieved, so that multi-channel measurement can be performed quickly. Things.

(First Embodiment) Hereinafter, based on the configuration example of the apparatus of the present invention shown in FIG. 1, the apparatus according to the present invention is divided into a case where it operates in a master state and a case where it operates in a slave state. explain.

(1) Operation in Master Mode This case is a case where 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 substantially operate, and the description thereof will be given later in the operation as a slave.

In FIG. 1, first, the synchronization selecting section 71 selects whether to operate with the external synchronizing signal a (a1, a2) or to operate with the signal from the internal synchronizing signal generating section 50. As shown in FIG. 3, the external synchronization signal a includes an external trigger signal a1 indicating a timing when the measuring 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.

The measuring section 80 receives the trigger signal a1 within a period determined by the start / stop signal a2 obtained through the switches 21a and 60 and receives the trigger signal a1 by the number of channels set by the channel selecting section 73 (10 in FIG. 2). Channel) minutes.

On the other hand, as shown in the timing chart of FIG.
In response to the start / stop signal a2, the timing at the start is converted into two pulse groups (first pulse group) having a constant period T, and the stop timing is converted into three pulse groups (third group) having a constant period T. Pulse group), and receives a trigger signal,
And converts them into two pulses (second pulse group), 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 in the lower slave state.

(2) Operation in Slave State In this case, the switches 21a, 21b, and 60 are set to the S side (slave side) by the switching unit 72 in the panel 70. Therefore, when operating as a slave, the code conversion unit 22 does not operate. The conversion unit 20 receives the slave synchronization signal b from the higher-level master device 1 and outputs it through (see FIG. 2).

The gate generator 40 of the slave device 1 having received the slave synchronizing signal b from the host device 1 generates a gate signal c having a predetermined window time based on the slave synchronizing signal b.
(See FIG. 4).

The predetermined window time is a time from the time when the first pulse arriving after the lack of the pulse of the fixed period T in response to the slave synchronization signal b is received until the pulse group is included. It is designed to be. That is,
The window time is set so that each pulse group can be separated with a time during which a pulse of a constant period T is missing.

The counter 31 receives the slave synchronization signal b
And the gate signal c, each pulse group is separated, and the number of pulses is counted for each pulse group (see d in FIG. 4). Therefore, after counting a certain group of pulses, the counting is cleared, and when the next group of pulses comes, counting is performed from the beginning. The information decoding unit 32 generates a decoding start signal (e2 in FIG. 4) after counting two pulses, for example, from the counting result of the counter 31, and after counting one pulse, decodes the decoding trigger signal (e2). After generating e1) in FIG. 4 and counting the three pulses, a decoding stop signal (e2 in FIG. 4) is generated and sent to the measuring unit 80 to measure at these timings.

(Second Embodiment) In the first embodiment, when the device 1 performs a master operation, the decoding unit 3
0 and the gate generation unit 40 did not operate, but these were also operated during the master operation, and the measurement unit 80
Is operated by 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, both the master device and the slave device can measure at the same time. Specifically, in FIG. 1, the switch 60 may be omitted, and the output of the information decoding unit 32 may be directly input to the measuring unit 80.

(Third Embodiment) FIG. 5 is a diagram showing a configuration corresponding to a third embodiment, and the same reference numerals in FIG. 5 as those in FIG. 1 indicate the same functions. In the present invention, as shown in FIG. 5, a first terminal 90a is connected to a master device,
The second terminal 90b is connected to a lower slave device. When the device is the master, the switch unit 100 is set to M (master side) and the code generator 11
At 0, a slave synchronization signal b is generated and transmitted to the slave via the second terminal 90b. In the case of a slave, the slave synchronizing signal b from the master device is sent to the first terminal 9.
The signal is received at 0a and transmitted as it is to the lower slave via the second terminal 90b.

The code generator 110 combines the function of the synchronization signal generator 50 and the function of the code converter 22 in FIG. Further, a configuration may be adopted in which a synchronization signal is externally received instead of the synchronization signal generation unit 50.

(Explanation of Operation of Radio Wave Service Area Evaluation Apparatus) FIG. 6 is a schematic diagram showing a state of a radio wave using the radio wave service area evaluation apparatus 1 according to the embodiment. The measurer
The radio wave service area evaluation device 1 according to the embodiment of the present invention is mounted on the measurement vehicle 200 and moves within a telephone service area where a plurality of base stations 300 are installed. Then, while moving, each point receives the radio wave 4 from each base station 300, measures the received signal level of each radio wave 4, and evaluates each radio wave state at the corresponding point.

As described above, the radio wave 400 transmitted from each base station 300 to each mobile station (not shown) of the mobile phone includes a W-CDMA signal. In this W-CDMA signal, a common pilot channel (CP) spread with different codes in one frequency band is used.
ICH) 9, a synchronization channel (SCH) (not shown), and a plurality of data channels (CH1 to CHN) (not shown) are included in a state where signals are combined. As shown in FIG. 7, the common pilot channel (CPICH) 9 is a code (for example, PN) generated by a 9-bit primary code 9a and a 4-bit secondary code 9b that specify a base station.
Code).

Further, a 9-bit primary code 9a
Is composed of a 6-bit group code and a 3-bit cell code. Therefore, each base station 300 has 9
Since it is specified by a bit, one channel (CH) code of 2 ⁹ = 512 codes is allocated to each base station 300. The 9-bit primary code 9a is, for example, W-CD in a state of being spread spectrum by a PN code.
Since it is incorporated in the MA signal, the radio wave service area evaluation device 1 mounted on the measurement vehicle 200 has 512 types of Ps in advance.
N codes are prepared and the original common pilot channel (CPI
CH) 9 to extract the base station 3 from which the radio wave 400 is transmitted.
00 is specified.

Although not shown, the radio service area evaluation apparatus 1 mounted on the measuring vehicle 200 has a display and an operation unit provided on the front of the case. The operation unit is provided with a measurement start / end button, a scroll (arrow) button, a selection button, a rotary knob, and a plurality of function buttons. Further, a connector for an AC adapter and a serial port for connection to an external PC (personal computer) are attached to the side surface of the case.

Each channel (CH) allocated to each of the 512 base stations 300 is stored in the buffer memory of the apparatus.
An area for writing the signal level of the corresponding channel calculated by the arithmetic processing unit for every ms is formed. This buffer memory is constituted by a FIFO memory, and stores, for example, each signal level for the latest 30 minutes.
The level calculator, 1 to 3 stored in the signal data memory
N in each of 32 channels (10 in the description of FIG. 2)
) Data is statistically processed and written to the level memory. In the level memory, a channel (CH) code, Ec (received energy per channel) calculated by an aggregate method, Ec / No (received energy Ec per channel and received power density) for each of channels 1 to 32 No), S
The IR (ratio between signal level and interference signal level) is written.

The data extraction unit extracts N unit data of the channel specified by the display format instruction unit from the 32 channels stored in the signal data memory, and sends the extracted data to the data editing unit.

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 Is graphically displayed as characteristic data on the upper part of the display screen.

Further, the data editing unit converts the above-mentioned channel (CH) code, Ec, Ec / No, and SIR data of each of the channels 1 to 32 stored in the level memory in a format of a list. Display output to the lower part of the display screen of the display unit.

Note that the list is not displayed all at once due to the space of the display screen, but the operator can select a channel to be displayed by operating a scroll key.

Further, on the display screen of the display, the current position of the measuring vehicle 200 obtained from the GPS satellite is displayed in the form of latitude and longitude. Also this

Further, on the display screen of the display device, a plurality of function keys such as "level conversion" and "save" are displayed, and the measurer can specify the corresponding function button on the operation section to specify the function key. Any function key can be selected.

For example, when the "Save" function key is designated by the function button of the operation unit, the contents stored in the signal data memory are written to the FD or IC card mounted on the FD mounting unit or the IC card mounting unit.

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, each base station 30 serving another cell is also used.
Many radio waves 400 from 0 are also received. In that case, FIG.
As shown in the figure, each base station 300 is allocated to each radio wave service area evaluation device 1, and for the measurer, for example, the radio wave state of the radio wave 400 having a large signal level transmitted from each base station 300 at each point in the telephone service area. Can be reliably evaluated. In this case, the FD data written by the plurality of devices is processed by a processing device such as a personal computer, and the radio wave service area is evaluated.

[0049]

As described above, the radio wave service area evaluation device of the present invention is configured to be connected to a plurality. Therefore, one radio service area evaluation device
The size, weight, and power consumption are reduced, so that the measurer can carry the device, walk behind the alley, and measure data in the radio wave service area.

As described above, in the radio service area evaluation apparatus, the function of the master and the slave can be switched, and the timing signal can be decoded and measured between the master and the slave with a simple time-series signal. Allocating the radio wave service area evaluation device to each device connected in series reduces the number of devices to be measured, resulting in shorter measurement time for one measurement and faster repeat measurement. it can. That is, a processing speed corresponding 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 device according to an embodiment of the present invention.

FIG. 2 is a diagram showing a usage example using a plurality of radio wave service area evaluation apparatuses according to an embodiment of the present invention;

FIG. 3 is a time chart illustrating an operation of the master device according to the embodiment;

FIG. 4 is a time chart illustrating an operation of the slave device according to the embodiment;

FIG. 5 is a block diagram showing a radio wave service area evaluation device according to another embodiment of the present invention.

FIG. 6 is a schematic diagram showing measurement of a radio wave state using the radio wave service area evaluation device.

FIG. 7 is a frame configuration diagram of a common pilot channel embedded in a W-CDMA signal.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Radio wave service area evaluation apparatus, 20 ... Conversion part, 30
... Decoding unit, 40 ... Data generation unit, 72 ... Switching unit, 80 ...
Measurement section, 90a: first terminal, 90b: second terminal, 1
00: switch unit, 110: code generation unit, 120: decoding timing generation unit.

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 5K022 EE02 EE31 5K042 AA06 BA00 CA13 CA23 DA19 DA21 EA01 EA14 FA01 FA11 FA15 GA12 JA01 5K067 AA33 CC10 DD44 EE02 EE10 HH24 LL01 LL05 LL11

Claims (6)

[Claims] 1. A radio service area evaluation for receiving a W-CDMA signal transmitted from a plurality of base stations to each mobile station and evaluating a radio service area of each base station based on the received signal level. A switching unit (72) for setting the radio wave service area evaluation device as a master or a slave; and, when the radio wave service area evaluation device is set as a master by the switching unit, the switching unit (72). Measurement start information,
The measurement end information and the measurement take-in timing from outside are converted into a predetermined information code and output to the outside, or when the radio wave service area evaluation device is set as a slave by the switching unit, the predetermined information code is used. A conversion unit (20) that outputs the radio wave service area as it is to the outside, and when the radio wave service area evaluation device is set as a master by the switching unit, the radio wave service area evaluation device does not function and the radio wave service area evaluation device becomes a slave by the switching unit. If it is set, the decoding unit (30) that reproduces measurement start information, measurement end information, and measurement acquisition timing from the predetermined information code, and the radio wave service area evaluation device is set as a slave by the switching unit. If so, a gate for counting pulses within a predetermined time range from the predetermined information code The radio service area evaluation device equipped with a gate generator (40) for generating a degree. 2. A method for selecting a plurality of base stations, receiving a W-CDMA signal for a mobile station transmitted from the base station, receiving a start signal indicating a measurement start time, a trigger signal indicating a data acquisition time, and measuring An electromagnetic wave service area evaluation device (1) including a measuring unit (80) for measuring an electromagnetic wave service area of each of the base stations based on the level measured by an end signal indicating an end time. One of the radio wave service area evaluation devices sends measurement timing information to the other and causes it to be measured at the measurement timing.
A switching unit (72) for switching to a slave if the other is true; and, if the switching unit is set to a master, the start signal to a first predetermined number of pulse groups and the trigger signal to A signal indicating the end time is given to the second predetermined number of pulses in the third group.
To a predetermined number of pulse groups and transmit it to the radio wave service area evaluation device for operating as a slave as the temporary sequence of the measurement timing information. When the switching unit is set to the slave, the higher order radio wave A conversion unit (20) for receiving the measurement timing information from the service area evaluation device and enabling the measurement timing information to be output to a lower-level radio service area evaluation device; and when the switching unit is set as a slave, A first predetermined number of pulse groups from the temporal sequence timing information,
A gate generation unit (40) for generating a gate signal having a window time corresponding to the pulse group in order to separate the pulse into a second predetermined number of pulse groups and a third predetermined number of pulse groups; If the slave is set, a decoding start signal, a decoding trigger signal, and a decoding end signal are generated by counting the number of pulses in each window time of the gate signal from the gate generation unit, and these are used as the start signal. ,
A radio service area measuring device, comprising: a decoding unit (30) for sending the signal to the measurement unit for measurement instead of the trigger signal and the end signal. 3. The radio service area evaluation device according to claim 2, wherein the start signal, the trigger signal, and the end signal are received from the outside when the switching unit is set to the master. 4. A gate generator and a decoder operate when the switch is set as a master by the switch, and the measuring unit uses a decoding start signal, a decoding trigger signal, and a decoding end signal from the decoding unit. The radio wave service area measuring device according to claim 2, which operates. 5. A plurality of base stations are selected, a W-CDMA signal for mobile stations transmitted from the base station is received, and a radio service area of each base station is evaluated based on a level of the received signal. A radio wave service area evaluation device (1) including a measuring unit (80), wherein one of the plurality of radio wave service area evaluation devices transmits measurement timing information to the other and causes the radio wave service area evaluation device to perform measurement at the measurement timing. A switching unit (72) for serving as a master when the one corresponds to the above, and a slave for the other one; a first terminal (90a) for connecting to the master; (90b), a first predetermined number of pulses indicating a measurement start time, a second predetermined number of pulses indicating a data acquisition time, and a third predetermined number indicating a measurement end time Pal A code generation unit (110) for generating a group of data as a series of time-series signals; and, when set as a master by an instruction from the switching unit, send an output of the code generation unit to the second terminal. , When set as a slave, a switch unit (100) for coupling the first terminal and the second terminal, the first predetermined number of pulse groups, the second predetermined number of pulse groups, and 3, a decoding timing generator for decoding the measurement start, trigger signal, and measurement end by counting the number of pulses of each pulse group and sending it to the measurement unit for measurement. (1
20) The radio wave service area measuring device characterized by comprising: 6. The radio wave service area evaluation device, wherein a plurality of the radio wave service area evaluation devices are connected, whereby one radio wave service area evaluation device is set as a master by a switching unit of the radio wave service area evaluation device,
The said radio | wireless service area evaluation apparatus is set as a slave by the switching part of the apparatus, and the said radio | wireless service area evaluation apparatus can share the measurement of a received signal level with said each said claim 1, 2, 3, 4, Or the radio wave service area evaluation device according to 5.