JPH08254559A - Mobile apparatus for measuring propagation of radio wave and analyzer therefor - Google Patents

Abstract

PURPOSE: To obtain a mobile apparatus for measuring the propagating state of radio wave continuously and automatically and displaying and printing the state diagram. CONSTITUTION: The mobile apparatus for measuring the propagating state of radio wave comprises a position measuring unit 103 for receiving a GPS satellite signal to output a position data, a radio wave propagation measuring unit 102 for receiving an objective radio wave and measuring the receiving state thereof, a recorder 105 for recording the measurement data obtained from the radio wave propagation measuring unit 102 while sorting according to the position data obtained from the position measuring unit 103, and a display 203 for displaying a symbol indicative of the value of measurement data on a map displayed by map information according to the position data recorded in the recorder 105.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio wave propagation movement measuring device and an analyzing device for this measuring device which can be used for measuring the propagation state of radio waves used in, for example, mobile phones.

[0002]

2. Description of the Related Art In the field of mobile communication such as a mobile phone, the electric field strength of radio waves in the area is specified in order to specify the area where communication is possible.
Work to measure the error rate is required. Conventionally, bring a map drawn on the paper to the measurement point and manually measure the radio wave propagation status (electric field strength, error rate, delay spread, etc.) using the propagation measurement antenna and the propagation measurement unit. The data and the map are associated and recorded on paper. In the office, we manually create a state diagram of the radio wave propagation situation on a map on the paper.

[0003]

As described above, conventionally, since the measurement data is acquired and the data is processed manually, a large amount of labor and time are required, and a large number of devices installed for mobile communication are required. It is difficult to measure the radio transmitter. An object of the present invention is to provide a radio wave propagation movement measuring device capable of measuring a radio wave propagation state in a short time and displaying the measurement result on a map, and an analyzing device used for the same.

[0004]

According to claim 1 of the present invention, a position measuring device for receiving a GPS satellite signal and outputting position data, a radio wave propagation measuring device for measuring a radio wave propagation situation, and this radio wave propagation measuring device. A recording device that sorts and records the measurement data measured by the position data obtained by the position measurement device, and these position measurement device, radio wave propagation measurement device,
The present invention proposes a radio wave propagation movement measuring device by means of a conveying means that conveys a recording device as a unit.

According to claim 2 of the present invention, the radio wave propagation movement measuring device proposed in claim 1 is provided with map information, a map display device for reading the map information and displaying a map, and a position for the map display device. We propose a configuration in which a display device that displays a symbol having a shape corresponding to the value of the measurement data measured by the radio wave propagation measurement device is added to the position on the map specified by the position data measured by the measurement device.

According to the radio wave propagation movement measuring apparatus proposed in claim 1 of the present invention, by moving the carrier means,
The position data can be continuously and automatically obtained, and each time the position data is obtained, the measurement data obtained by the radio wave propagation measuring device is recorded in the recording device together with the position data. The measurement data can be continuously recorded together with the position data.

At the same time, according to the radio wave propagation movement measuring device proposed in claim 2, the measurement result of the radio wave propagation can be displayed on the map at the moving point while the carrier means is moving. Further, according to claim 3 of the present invention, the position data and the measurement data recorded in the recording device of the radio wave propagation movement measuring device proposed in claim 1 are read by a map display device installed in another place, and each of the measured regions is read. It proposes an analyzer that displays the measured data value of the measurement position on a map.

By separating this analysis device from the radio wave propagation movement measuring device, there is an advantage that the radio wave propagation movement measuring device mounted on the conveying means can be made light and compact.
Further, in claims 4 to 6 of the present invention, the ID number sent by the radio wave transmitted from each radio wave transmitter is detected, and the radio wave transmitter from which the radio wave is transmitted is distinguished from the ID number. The present invention proposes a radio wave propagation movement measuring device and an analyzing device for separately sorting and recording in a recording device and displaying the measured data value on a map.

According to the radio wave propagation movement measuring device and the analyzing device proposed in claims 4 to 6, the transmitter of the radio wave to be measured can be specified, and the data arrangement can be further simplified. can get.

[0010]

FIG. 1 shows an embodiment of the radio wave propagation movement measuring device proposed in claim 1 and the analyzing device proposed in claim 3 of the present invention. In the figure, 100 is a radio wave propagation movement measuring device, and 200 is an analyzing device. The radio wave propagation movement measuring device 100 includes a propagation measuring antenna 101, a radio wave propagation measuring device 102, a position measuring device 103, a recording device 105, measurement data A obtained from the radio wave propagation measuring device 102 and the position measuring device 103, and a position. It can be configured by the data processing unit 104 that performs data processing for writing the data B in the recording device 105.

The radio wave propagation measuring device 102 includes a receiving device for receiving the frequency of the radio wave to be measured, and an electric field intensity measuring device (for example, spectrum analyzer) or radio wave transmitting device for measuring the electric field intensity of the electric wave received by the receiving device. The error rate measuring device that measures the error rate by receiving the pseudo signal (random pulse) sent from the device and detecting the mismatch with the random pulse sent, or the radio wave sent from the radio wave transmitter is the building It can be configured by a measuring device or the like that measures delay spread and the like that occurs when the light is reflected by a mirror or the like and arrives via a plurality of paths. An AD converter for converting the measurement result into a digital code is built in these measuring instruments, and digitally encoded measurement data A is output.

On the other hand, the position measuring device 103 can be constituted by a position measuring system which mainly receives GPS satellite radio waves and outputs its own position in latitude and longitude. This type of position measurement system can be configured by the antenna 10 and the receiver 11 of a device which is already called a car navigation system or the like and is commercially available. Position data corresponding to the latitude and longitude of the current position is output from the receiver 11 in digital code. The position data output from the receiver 11 is interpolation-controlled by the interpolation correction unit 12 and output as position data B. For example, a geomagnetic sensor 13, a gyro sensor 14, and a vehicle speed sensor 15 are connected to the interpolation correction unit 12, and the detection signals of these sensors 13 to 15 are used to interpolate position data when satellite radio waves cannot be received in a tunnel, for example. , And the continuity of the position data B is maintained.

The measurement data A and the position data B are input to the data processing unit 104, and the data processing unit 104 causes the recording device 1 to operate.
Data processing for recording in 05 is performed. As this data processing, for example, if the position data output from the receiver 11 is output in a time series, the position data is output even when the device is stationary, and if this is sequentially recorded, the recording medium becomes useless. Position data, position data,
That is, for example, it is detected that the camera has moved 1 meter, the measurement data A is taken in every time the movement is detected, and the position data B and the measurement data A are recorded in the same recording address.

Therefore, in the recording device 105, the position data B and the measurement data A are sorted and recorded for each measuring address for each 1 meter for each recording address. The recording device 105 may be a semiconductor memory, a floppy disk, a hard disk, a magneto-optical disk, or the like. The radio wave propagation measuring device 102 (including the propagation measuring antenna 101), the position measuring device 103, and the recording device 105 are the minimum necessary configuration of the radio wave propagation movement measuring device 100. By mounting the radio wave propagation movement measuring device 100 of this configuration on an automobile, or by mounting it on a dolly or the like and moving it, a position automatically composed of latitude and longitude is reached every time the movement amount reaches a predetermined value, for example, 1 meter. The data B and the measurement data A for knowing the radio wave propagation situation at that position are recorded in the recording device 105.

Here, it is possible to manually move the radio wave propagation movement measuring device 100 by making it small and lightweight. Therefore, in this specification, a container to be manually transported is defined as a transporting means, and a means for mounting and moving the transporting means (automobile, trolley, person, etc.) is defined as a transporting means. When the radio wave propagation movement measuring device 100 is configured to be mounted on a vehicle, it is conceivable that the analysis device 200 is integrated with the radio wave propagation movement measuring device 100. However, here, a case will be described in which the analysis device 200 is separated from the radio wave propagation movement measurement device 100, and after the movement measurement, the measurement result is displayed on a map and printed out at an office or the like.

The analysis device 200 processes the map information database 201 storing the map information C and the map information C read from the map information database 201 to define the display area of the map, and selects and displays it on the display device 203. The data processing unit 202, the printer 204, and the image recording device 205, if necessary.

The data processing unit 202 receives the map information C and the measurement data A and position data B read from the recording device 105. The measurement data A is converted by the data processing unit 202 into a symbol having a shape corresponding to the measurement data value. A symbol, a code, a character, etc. can be used as the shape of the symbol. For example, when the measurement data represents the electric field strength, for example, the measured value of the electric field strength is 0 dBm.
In the case of, the letter W is assigned as a symbol, and -10 dBm
In the case of, the character X is assigned, and in the case of -20 dBm, the character Y is assigned.
, And the letter Z in the case of −30 dBm. The data processing unit 202 converts the measurement data A read from the recording device 105 into a character code representing a character corresponding to the measurement value, and the character is a graphic determined by the map information C according to the latitude / longitude given by the position data B. It is displayed at the coordinate position corresponding to the latitude and longitude on the coordinates.

FIG. 2 shows an example of a state diagram. The case where the radio wave transmitter 17 is attached to the corner of the building 16 is shown. A character W indicating that the electric field strength is strong is displayed in a portion near the radio wave transmitter 17. When the distance from the radio wave transmitter 17 is increased, the characters representing the electric field strength are changed to the characters X, Y and Z representing that the electric field strength is low. In particular, in the shaded areas of the buildings 16, 18, 19, and 20, Z having a low electric field strength is displayed, and it is understood that radio waves are hard to reach.

The printer 204 is used to print the image on the paper with the measurement data A displayed on the display device 203 as needed. Further, it is used to record the map displayed on the display device 203 and the measurement result as a graphic image in the image recording device 205 as needed. By recording the map and measurement result as graphic image data in this way, when displaying it again,
The display device 20 without performing the processing of the data processing unit 202
3 can be displayed, and the time required for displaying can be shortened. Therefore, as the image recording device 205, a fixed disk or a magneto-optical disk having a large capacity can be used.

In the data processing unit 202, a symbol designating means 206 for setting which symbol to use and the displayed symbol from the actual position on the map, such as a road, due to a measurement error of the position measuring device 103. Position correction means 207 for correcting the display position when the display is off, and analysis condition setting means 208 for setting the map area and the like are provided.

FIG. 3 shows an embodiment in which the radio wave transmitter transmits a radio wave including an ID number. In this case, the radio wave propagation movement measuring device 100 is provided with the ID number detecting means 107, the ID data D detected by the ID number detecting means 107 is input to the data processing section 104, and the ID data D is measured data A and position data. A case in which the recording device 105 and B are configured to record is shown.

In order to provide the ID number detecting means 107, a distributor 106 is provided between the propagation measuring antenna 101 and the radio wave propagation measuring device 102, the received radio wave is distributed by the distributor 106, and one of the distributed radio wave signals is distributed. The unit is input to the ID number detecting means 107, and the ID number included in the radio wave is detected.
The radio wave transmitters are installed at intervals of several hundred meters, and the radio wave areas to be transmitted often overlap each other. For such a case, the ID number is transmitted only at the time assigned to each radio wave transmitter. In this way, consideration is given so that the ID numbers are not overlapped and transformed into other numbers.

The ID number detecting means 107 receives the received ID
Although all the numbers are detected, by setting the ID number of the radio wave transmitter to be measured in the data processing unit 104, the measurement data A of the radio wave of the set ID number and the position data B are recorded together with the ID number. Record at 105. The number of IDs that can be set in the data processing unit 104 is about 2 to 3, and the radio waves transmitted from many radio wave transmitters are narrowed down to about 2 to 3 waves and measured.

Reference numeral 108 indicates an ID number setting means for setting an ID number to be measured in the data processing unit 104. The setting of the ID number setting means 108 and the symbol setting means 2
The combination of the settings of 06 sets a symbol for each ID number, and further inputs the position of the radio wave transmitter to be measured from the radio wave transmitter position input means 209 together with the ID number,
The measurement result is displayed on the map together with the position of the radio wave transmitter 17. Therefore, the measurement results can be displayed and printed out for each radio wave transmitter.

FIG. 4 shows a flow chart for explaining the outline of a program for operating the analysis apparatus 200 according to the present invention. In step S ₁ , the area of the map information is designated and read, and the correspondence between the position of the radio wave transmitter to be measured and the ID number is input. In step S ₂ , the measurement data is read from the recording device 105, in step S ₃ , the symbol corresponding to the type of measurement data, the ID number, etc. is designated, and in step S ₄ , the symbol is mapped to the position on the graphic according to the position data. _{At 5} , the symbol is displayed on the display device 203.

Step S₆, S₇, S₈Was displayed
Position correction when the symbol is displaced from the actual position
The position is corrected by the means 207, and step S₉, S_Ten,
S₁₁, S ₁₂The analysis conditions set by the analysis condition setting means 208 in
Display the state diagram according to the conditions (change of map size etc.),
Step S with the desired analysis conditions obtained₁₃Moved to
Whether the analysis result is recorded in the image recording device 205,
If you select the squid and record, step S₁₄
The memory operation is executed with and the process ends.

[0027]

As described above, according to the present invention, the position data B and the measurement data A are recorded as a pair at the same address of the recording device 105 as the position is moved. Can be read in pairs (sorted). As a result, a symbol having a shape corresponding to the value of the measurement data can be displayed at the corresponding position on the map according to the position data B.

Particularly, since the position data B and the measurement data A can be sequentially and automatically recorded in the recording device 105 according to the movement of the measurement device, the measurement data A and the position data B can be recorded.
By reading, the state diagram showing the propagation state of the radio wave can be associated with the map and drawn fully automatically without manpower. Therefore, the radio wave propagation states of a large number of radio wave transmitters can be measured in a short time.

Further, by providing the ID number detecting means 107 in particular, it is possible to specify and measure the radio wave transmitters to be measured, and the radio waves of each radio wave transmitter are individually measured even in the area where the radio waves overlap. The advantage that can be obtained is obtained. Further, the position correction means 207 is provided, and the display device 203
When the position of the symbol displayed in is deviated from the actual position, it can be corrected. Therefore, the image recorded in the image recording device 205 can be recorded by correcting the position of the symbol. Since the image read out from the recording device and displayed is correctly corrected and displayed, the analysis can be performed based on the correct measurement result.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing an example of a state diagram obtained by the radio wave propagation movement measuring device according to the present invention.

FIG. 3 is a block diagram showing a modified embodiment of the present invention.

FIG. 4 is a flowchart illustrating an operation of the radio wave propagation movement measuring device shown in FIGS. 1 and 3.

[Explanation of symbols]

 100 Radio Wave Propagation Mobile Measuring Device 101 Propagation Measuring Antenna 102 Radio Wave Propagation Measuring Device 103 Position Measuring Device 104 Data Processing Unit 105 Recording Device 107 ID Number Detecting Unit 108 ID Number Setting Unit 200 Analyzing Device 201 Map Information Database 202 Data Processing Unit 203 Display Device 204 Printer 205 Image recording device

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Yasumasu Yasumasu 1-32-1, Asahi-cho, Nerima-ku, Tokyo Within Advantest, Inc. (72) Inventor Yusuke Okawara 1-32-1-1, Asahi-cho, Nerima-ku, Tokyo Stock company Advantest (72) Inventor Koichi Aoyagi 1-32-1 Asahi-cho, Nerima-ku, Tokyo Stock company Advantest (72) Inventor Kazuo Uchikawa 1-32-1 Asahi-cho, Nerima-ku, Tokyo Shares Within Advantest

Claims (6)

[Claims] 1. A. First Embodiment A position measuring device that receives GPS satellite signals and outputs position data; B. A radio wave propagation measuring device that receives radio waves to be measured and measures the reception state; A recording device that sorts and records the measurement data obtained by the radio wave propagation measuring device according to the position data obtained by the position measuring device; A radio wave propagation movement measuring device comprising: the position measuring device, the radio wave propagation measuring device, and a carrying unit that integrally houses the recording device so as to be carried. 2. In addition to the radio wave propagation movement measuring device according to claim 1, A. A display device including map information and map display means for reading and displaying the map information, and position display means for displaying a position on the map specified by the position data measured by the position measuring device. , B. A radio wave propagation movement measuring device, characterized in that a measurement value display means for displaying a symbol having a shape corresponding to a value of measurement data measured by the radio wave propagation measuring device for each position measured by the position measuring device is added. . 3. The radio wave propagation measuring device according to claim 1, which is configured separately from the radio wave measuring device according to claim 1. A display device including map information and map display means for reading and displaying the map information, and position display means for displaying the position on the map specified by the position data recorded in the recording device, B. A radio wave propagation movement measuring device configured to include a measurement value display means for displaying a symbol having a shape corresponding to the value of the measurement data recorded in the recording device at a position on the map specified by the position data. Analysis device. 4. The radio wave propagation movement measuring device according to claim 1, further comprising an ID number detecting means for detecting an ID number sent by a radio wave to be measured, and recording the ID number together with the measurement data and the position data. A radio wave propagation movement measuring device characterized by being recorded in. 5. The measurement data and the position data with ID numbers obtained by the radio wave propagation movement measuring device according to claim 4 are ID.
3. The radio wave propagation movement measuring device according to claim 2, further comprising display means for sorting the numbers and displaying them on a map. 6. An ID number is attached to the measurement data and the position data, which are obtained by the radio wave propagation measuring device according to claim 4.
4. The analysis device for a radio wave propagation measuring device according to claim 3, further comprising display means for sorting the numbers and displaying them on a map.