JP3887669B2 - Communication state measuring apparatus and communication state measuring method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a communication state measuring device and a communication state measuring method for measuring a communication state with a base station in an area of a mobile telephone system.To the lawIt is related.
[0002]
[Prior art]
When providing a mobile telephone service, it is required that a good communication state can be obtained throughout the communicable area. However, depending on the setting of the antenna direction of the base station, radio wave output, etc., a place with a poor communication state may occur even within the area due to fading, multipath, interference waves, and the like.
[0003]
Conventionally, in order to find a position where such a communication state is bad, a lot of workers are sent to various places in the area of the mobile telephone system to measure the radio wave state. Whenever a location with a poor communication status is found, the settings of the antenna direction of the base station, radio wave output, etc. are adjusted to eliminate the location with such a poor communication status, and good communication is possible throughout the area. The state is obtained.
[0004]
[Problems to be solved by the invention]
However, a method of measuring a radio wave state at each place in the area by a large number of workers and finding a position having a poor communication state requires a lot of labor costs. In addition, if it is attempted to perform measurement with a small number of people in order to reduce labor costs, it takes a long time to measure the radio wave condition in the entire area.
[0005]
  The present invention has been made to solve the above-described problem, and a communication state measuring apparatus capable of accurately and accurately finding a position where a communication state is bad in an area of a mobile telephone system at a low cost and in a short time. Communication state measurement methodThe lawThe purpose is to obtain.
[0006]
[Means for Solving the Problems]
  In order to solve the above-mentioned problems, a communication state measuring apparatus of the present invention has a circuit that simulates a communication circuit of a mobile telephone, and a predetermined radio wave state when communicating with a base station using the circuit. A platform circuit that measures the characteristic values of theIt has a GPS receiver that receives signals from GPS satellites.Position detection means for detecting the current position and each predetermined characteristic value measured along the time series by the platform circuit., RankSequentially recorded in association with the information of the current position detected by the position detection meansIn addition, the reception status of signals from GPS satellites is recorded in association with current position information.Recording means.
[0007]
  By using this communication status measurement device, it is possible to grasp the radio wave status of each location in the area simply by moving the communication status measurement device on the mobile body. A location with a poor communication state can be found at low cost and in a short time.Further, the error between the reception position of the signal from the GPS satellite and the measurement position of the predetermined characteristic value is almost eliminated, and the position where the communication state in the area of the mobile telephone system is bad can be found more accurately. Further, it is possible to know the communication state at each point in the area in consideration of the reception state of the signal from the GPS satellite.
[0008]
  Further, the communication state measuring device of the present invention includes a position detecting means in addition to the communication state measuring device of the above invention., GA trigger signal is output in synchronization with the signal from the PS satellite, and the recording means associates each predetermined characteristic value when the trigger signal is output with information on the current position with respect to the time of reception of the signal from the GPS satellite. To record.
[0009]
By using this communication status measurement device, the error between the signal reception position from the GPS satellite and the measurement position of the predetermined characteristic value is almost eliminated, and the location where the communication status is poor in the area of the mobile telephone system is further improved. Can be found accurately.
[0010]
Furthermore, the communication state measuring device of the present invention measures each predetermined characteristic value when the platform circuit is supplied with a trigger signal in addition to the communication state measuring device of each of the above inventions, and supplies it to the recording means. .
[0011]
When this communication state measuring device is used, a predetermined characteristic value is measured when a signal from the GPS satellite is received. Therefore, the reception position of the signal from the GPS satellite, the measurement position of the predetermined characteristic value, and The error can be reduced.
[0012]
Furthermore, the communication state measuring device of the present invention outputs a trigger signal in synchronization with any of the C / A code, P code and Y code from the GPS satellite in addition to the communication state measuring device of each of the above inventions. is there.
[0013]
When this communication state measuring device is used, since the measurement timing of a predetermined characteristic value is determined based on the detection timing of the code used for measuring the distance to the GPS satellite, it is ensured that the signal from the GPS satellite It is possible to reduce the error between the reception position of the first and the measurement position of the predetermined characteristic value.
[0014]
Further, the communication state measuring device according to the present invention, in addition to the communication state measuring device according to each of the inventions described above, the position detecting means can detect up to a GPS satellite in any one of a code string of C / A code, P code and Y code. The trigger signal is output in synchronization with the timing of the code used to measure the distance.
[0015]
When this communication state measuring device is used, the measurement timing of a predetermined characteristic value can be determined at a desired integer multiple of the period of any one of the C / A code, P code, and Y code. it can.
[0016]
Furthermore, the communication state measuring device according to the present invention, in addition to the communication state measuring device according to each of the inventions described above, allows the position detection means to output a trigger signal according to a predetermined schedule even when the signal from the GPS satellite is interrupted for a predetermined time or more. Output.
[0017]
If this communication state measuring device is used, it is possible to continuously measure the radio wave state at each point according to a predetermined schedule even when the reception state of the signal from the GPS satellite is temporarily poor.
[0018]
Furthermore, the communication state measuring device of the present invention is a car navigation system in which the position detecting means includes a GPS receiver and at least one of a vehicle speed pulse sensor and a gyro sensor in addition to the communication state measuring device of each of the above inventions. It is.
[0019]
By using this communication status measurement device, it is possible to accurately measure the current position even if the reception status of the signal from the GPS satellite is temporarily poor, while making the device inexpensive by using a car navigation system. The radio wave condition at a point can be accurately measured.
[0022]
  Further, the communication state measuring device of the present invention includes a position detecting means in addition to the communication state measuring device of each of the above inventions.The correction information is received and the current position information is corrected based on the correction information.It has a DGPS receiver and the recording meansUsed for correction of current position information by DGPS receiverThe reception state of the correction information is recorded in association with the current position information.This DGPS receiver may receive correction information by the FM multiplexing method.
[0023]
By using this communication status measurement device, the current position can be measured with high accuracy based on DGPS, and the communication status at each point in the area can be determined in consideration of the reception status of DGPS correction information. I can know.
[0024]
  The communication state measurement method of the present invention measures a predetermined characteristic value indicating a radio wave state when communicating with a base station by a circuit simulating a communication circuit of a mobile phone along a time series,By a GPS receiver that receives signals from GPS satellitesThe step of detecting the current position and each predetermined characteristic value measured along the time seriesCurrentRecord sequentially in association with location informationAnd a step of recording the reception state of the signal from the GPS satellite in association with the current position information.
[0025]
  By using this communication status measurement method, it is possible to grasp the radio wave status of each place in the area simply by measuring the radio wave status using this method while moving within the area. A bad position can be found at low cost and in a short time.Further, the error between the reception position of the signal from the GPS satellite and the measurement position of the predetermined characteristic value is almost eliminated, and the position where the communication state in the area of the mobile telephone system is bad can be found more accurately. Further, it is possible to know the communication state at each point in the area in consideration of the reception state of the signal from the GPS satellite.
[0036]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0037]
Embodiment 1 FIG.
FIG. 1 is a block diagram showing a configuration of a communication state measuring apparatus 1 according to Embodiment 1 of the present invention.
[0038]
In the communication state measuring apparatus 1 shown in FIG. 1, the platform circuit 11 has a circuit simulating a mobile telephone communication circuit such as a mobile phone, a PHS (Personal Handyphone System) machine, etc., and a base station (not shown) by the circuit This is a circuit for measuring a predetermined characteristic value such as a BER (Bit Error Rate) value and an RSSI (Receive Signal Strength Indicator) value indicating the radio wave state when communicating with each other in time series. Note that the circuit simulating the communication circuit of the mobile telephone is a part of the internal circuit of the mobile telephone that is extracted from the baseband circuit that communicates with the base station using a predetermined protocol.
[0039]
The GPS receiver 12 is position detecting means for receiving radio waves from a GPS (Global Positioning System) satellite (not shown) and detecting the current position.
[0040]
Further, the recording device 13 uses a predetermined characteristic value such as a BER value or an RSSI value measured at a predetermined time interval by the platform circuit 11 as information on the current position detected by the GPS receiver 12 at the measurement time. It is a recording means for sequentially recording in association with a recording medium 21 such as a hard disk device (hereinafter referred to as HDD). Note that the recording device 13 may be realized as a computer having a built-in HDD as the recording medium 21 and receive signals from the platform circuit 11 and the GPS receiver 12 via an interface such as a USB (Universal Serial Bus). Good.
[0041]
Next, the operation of the above apparatus will be described. That is, a communication state measurement method according to Embodiment 1 of the present invention will be described.
[0042]
The platform circuit 11 attempts to establish a line with the base station, measures a predetermined characteristic value such as a BER value and an RSSI value at a predetermined time interval (for example, 1/10 second interval) at that time, This is sequentially supplied to the recording device 13.
[0043]
On the other hand, the GPS receiver 12 receives radio waves from GPS satellites, calculates the current position of the communication state measuring apparatus 1 as needed, and supplies latitude and longitude, which are position information of the current position, to the recording apparatus 13.
[0044]
When the characteristic value is supplied from the platform circuit 11 at a predetermined time interval, the recording device 13 records the characteristic value on the recording medium 21 together with the latitude and longitude of the current position at that time. FIG. 2 is a diagram illustrating an example of a format of measurement data recorded on the recording medium 21 of the communication state measurement device 1 illustrated in FIG.
[0045]
The communication state measuring device 1 that operates in this way is installed or arranged on a moving body such as an automobile, a motorcycle, a bicycle, and the like, and the mobile body is moved in the area, so that the radio wave state in various places in the area is obtained. Corresponding characteristic values are sequentially recorded on the recording medium 21.
[0046]
FIG. 3 is a diagram illustrating an example of the movement locus 32 of the communication state measurement apparatus 1 illustrated in FIG. As shown in FIG. 3, the communication state measuring apparatus 1 is moved in an area 31 so as to pass through the entire region as much as possible, for example, as a movement locus 32. As a result, characteristic values corresponding to the radio wave conditions at various places in the area 31 can be obtained. Therefore, the area 31 has jurisdiction so that the communication state is good throughout the area 31 based on the characteristic values at the various places. It is possible to adjust the setting of the base station (antenna direction, radio wave output, etc.).
[0047]
As described above, according to the first embodiment, a circuit that simulates a communication circuit of a mobile telephone has a predetermined characteristic value indicating a radio wave state when communicating with a base station using the circuit. The platform circuit 11 that measures along the time series, the GPS receiver 12 that detects the current position, and the predetermined characteristic values (BER value, RSSI value, etc.) measured along the time series by the platform circuit 11 at that time And a recording device 13 for sequentially recording in association with information (latitude and longitude) of the current position detected by the GPS receiver 12. As a result, it is possible to grasp the radio wave state of each place in the area 31 simply by moving the communication state measuring apparatus 1 in the mobile body by installing the communication state measuring apparatus 1 on the mobile body. A bad position can be found in a low cost and in a short time.
[0048]
Embodiment 2. FIG.
FIG. 4 is a block diagram showing a configuration of communication state measuring apparatus 1A according to Embodiment 2 of the present invention.
[0049]
In the communication state measuring apparatus 1A shown in FIG. 4, the platform circuit 11A has a function of measuring a predetermined characteristic value similarly to the platform circuit 11 of FIG. 1, and when a trigger signal is supplied from the GPS receiver 12A. It is a circuit that measures each predetermined characteristic value and supplies it to the recording device 13A. That is, as a result, the recording device 13A records each predetermined characteristic value when the trigger signal is output in association with the current position information.
[0050]
The GPS receiver 12A is a device that has a function of detecting the current position in the same manner as the GPS receiver 12 of FIG. 1 and outputs a trigger signal in synchronization with a signal received from a GPS satellite.
[0051]
FIG. 5 is a block diagram showing a configuration example of the GPS receiver 12A in FIG. In the GPS receiver 12A shown in FIG. 5, the antenna 101 is an antenna that senses radio waves from GPS satellites. The receiving circuit 102 is a circuit that receives radio waves from each GPS satellite via the antenna 101, demodulates the received signal, and extracts a C / A (Coarse Acquisition) code, a P (Precise) code, and a Y code. .
[0052]
Further, the decoding circuit 103 decodes the C / A code and the P (or Y) code that are spread spectrum PN (Pseudo-Noise) codes into data from the GPS satellites, and either code (for example, C / A code) is a circuit that calculates a pseudo distance to each GPS satellite based on the phase of the GPS satellite and outputs a timing signal synchronized with the code sequence of the code used for the calculation of the pseudo distance.
[0053]
The arithmetic circuit 104 is a circuit that calculates the current position based on pseudoranges, ephemeris information, almanac information, and the like for at least three GPS satellites obtained by the decoding circuit 103. The process for calculating the current position from these pieces of information may use a well-known method. Further, in order to reduce the error of the current position, pseudo distances from at least four GPS satellites are used.
[0054]
The trigger circuit 105 is synchronized with all of the timing signals output from the decoding circuit 103, that is, the timing signals synchronized with the code sequence of the code used for the calculation of the pseudo distance, or actually among the timing signals. This is a circuit that outputs a trigger signal in synchronization with only the timing signal for the pseudo distance used for calculation of the current position.
[0055]
Further, the recording device 13A records predetermined characteristic values such as a BER value and an RSSI value in association with the information on the current position detected by the GPS receiver 12A at the measurement time, similarly to the recording device 13 of FIG. The device has a function of sequentially recording on the medium 21, and further records a reception state of a signal (GPS signal) from a GPS satellite in association with information on the current position. FIG. 6 is a diagram showing an example of a format of measurement data recorded on the recording medium 21 of the communication state measurement device 1A shown in FIG.
[0056]
Next, the operation of the above apparatus will be described.
[0057]
In the GPS receiver 12 </ b> A, the receiving circuit 102 receives a signal from each GPS satellite via the antenna 101. The signal from the GPS satellite includes an L1 signal including a C / A code and a P (or Y) code, and an L2 signal including a P (or Y) code. The receiving circuit 102 demodulates the L1 signal and the L2 signal, extracts the C / A code and the P (or Y) code, and supplies the C / A code and the P (or Y) code to the decoding circuit 103.
[0058]
In the C / A code, one PN code is composed of 1023 bits. Since this C / A code has a bit rate of 1.023 MHz, the transmission time of the C / A code is 1 millisecond per PN code.
[0059]
The decoding circuit 103 decodes the PN code string from each GPS satellite into data, and supplies the data (ephemeris information, almanac information, and other information) to the arithmetic circuit 104.
[0060]
The decoding circuit 103 generates a C / A code or P (or Y) code similar to the C / A code or P (or Y) code from each GPS satellite, and generates the generated C / A code or P ( Alternatively, based on the phase error between the Y) code and the received C / A code or P (or Y) code, the signal transmission time from the GPS satellite to the GPS receiver 12A is calculated, and GPS signal is calculated from the signal transmission time. The pseudo distance between the satellite and the GPS receiver 12A is calculated and supplied to the arithmetic circuit 104.
[0061]
Further, the decoding circuit 103 supplies a timing signal to the trigger circuit 105 for each 1PN code of the received C / A code or P (or Y) code.
[0062]
The trigger circuit 105 supplies a trigger signal to the platform circuit 11 in synchronization with any of the timing signals. The trigger circuit 105 may output a trigger signal according to a predetermined schedule even when the signal from the GPS satellite is interrupted for a predetermined time or more and the timing signal from the decoding circuit 103 is interrupted for a predetermined time or more. .
[0063]
At this time, for example, when a timing signal is generated in synchronization with the PN code of the C / A code, the timing signal has a cycle of 1 millisecond. Therefore, when a trigger signal is output in synchronization with all timing signals, the trigger circuit 105 outputs the trigger signal at a cycle of 1 millisecond.
[0064]
On the other hand, there is a delay of 1 millisecond or more from the signal reception to the current position information output due to the computation by the computation circuit 104, and it is difficult for the computation circuit 104 to calculate the current position information in a 1 millisecond cycle. The trigger circuit 105 may output a trigger signal at a rate of once per N timing signals.
[0065]
For example, if the time required for the calculation of the current position information by the calculation circuit 104 is 100 milliseconds, the current position information can be calculated at a rate of once every 100 milliseconds, so that it is 100 (N = 100) times. At a rate of once, a trigger signal is output at a period of 100 milliseconds in synchronization with a timing signal corresponding to the PN code used for calculation of the pseudorange used at that time.
[0066]
In this case, a trigger signal may be output for any one or a plurality of codes among n (n ≧ 3) GPS satellites. Alternatively, the timing of the trigger signal may be determined by processing the reception timing of codes from a plurality of GPS satellites by averaging or the like.
[0067]
Here, the timing signal is periodically selected to generate the trigger signal. However, the decoding circuit 103 does not output the timing signal, and the trigger circuit 105 monitors the code string of the PN code and outputs a predetermined signal. You may make it output a trigger signal with a period.
[0068]
When a trigger signal is supplied from the trigger circuit 105 of the GPS receiver 12A, the platform circuit 11 measures a predetermined characteristic value at that time and supplies the measured characteristic value to the recording device 13A. On the other hand, the arithmetic circuit 104 of the GPS receiver 12A calculates the current position at the time of receiving a signal from the GPS based on the pseudo distance corresponding to the trigger signal, and supplies it to the recording device 13A.
[0069]
In this way, the current position information is supplied from the arithmetic circuit 104 of the GPS receiver 12A to the recording device 13A, and a predetermined characteristic value at the time of receiving the signal from the GPS satellite used to calculate the current position information. Is supplied from the platform circuit 11 to the recording device 13A.
[0070]
Then, the recording device 13A records the current position information (latitude and longitude of the current position) on the recording medium 21 in association with the predetermined characteristic value.
[0071]
At this time, the recording device 13A associates the reception state of the signal from the GPS satellite at that time obtained by the receiving circuit 102 of the GPS receiver 12A with the current position information and the predetermined characteristic value. To record.
[0072]
As described above, according to the second embodiment, the GPS receiver 12A outputs the trigger signal in synchronization with the signal from the GPS satellite, and the recording device 13A outputs each predetermined signal when the trigger signal is output. Is recorded in association with the current position information at the time of reception of the signal from the GPS satellite, so there is almost no error between the reception position of the signal from the GPS satellite and the measurement position of the predetermined characteristic value. It is possible to more accurately find a position where the communication state is bad in the area of the body phone system.
[0073]
Further, according to the second embodiment, when the platform circuit 11 is supplied with a trigger signal, each predetermined characteristic value is measured and supplied to the recording device 13A. Therefore, when a signal from a GPS satellite is received. Since the predetermined characteristic value is measured, the error between the reception position of the signal from the GPS satellite and the measurement position of the predetermined characteristic value can be reliably reduced. That is, the current position is output after the calculation time by the arithmetic circuit 104 from the time of signal reception, but the characteristic value is measured at the time of signal reception, so the error is reduced.
[0074]
Furthermore, according to the second embodiment, since the trigger signal is output in synchronization with either the C / A code and the P (or Y) code from the GPS satellite, it is used for measuring the distance to the GPS satellite. Since the measurement timing of the predetermined characteristic value is determined based on the detection timing of the code being detected, it is possible to reliably reduce the error between the reception position of the signal from the GPS satellite and the measurement position of the predetermined characteristic value. .
[0075]
Furthermore, according to the second embodiment, the GPS receiver 12A uses a code string used for measuring the distance to the GPS satellite in any one of the C / A code and the P (or Y) code. Since the trigger signal is output in synchronization with the timing, the measurement timing of the predetermined characteristic value is set to a desired integer (N) times the period of one of the code strings of the C / A code and the P (or Y) code. Can be determined.
[0076]
Furthermore, according to the second embodiment, the GPS receiver 12A outputs a trigger signal according to a predetermined schedule even when the signal from the GPS satellite is interrupted for a predetermined time or longer. Even when the reception state is temporarily bad, the radio wave state at each point can be continuously measured according to a predetermined schedule.
[0077]
Further, according to the second embodiment, the recording device 21A records the reception state of the signal from the GPS satellite at the time of measuring the current position in association with the information on the current position. The communication state at each point in the area can be known in consideration of the signal reception state.
[0078]
Embodiment 3 FIG.
FIG. 7 is a block diagram showing a configuration of communication state measuring apparatus 1B according to Embodiment 3 of the present invention.
[0079]
In the communication state measuring apparatus 1B shown in FIG. 7, the car navigation system 41 includes a GPS receiver 12A, a vehicle speed pulse sensor 51 that detects a vehicle speed pulse from a rotary encoder attached to an axle, and a gyro sensor that detects a running direction of the vehicle. 52, and a position detection means having a control circuit 53 for calculating the current position based on the current position information from the GPS receiver 12A and information from the vehicle speed pulse sensor 51 and the gyro sensor 52.
[0080]
The other components in FIG. 7 are the same as those in the second embodiment (FIG. 4), and the description thereof is omitted.
[0081]
Next, the operation of the above apparatus will be described.
[0082]
The car navigation system 41 corrects the current position information obtained by the GPS receiver 12A as necessary based on the vehicle speed information obtained by the vehicle speed pulse sensor 51 and the traveling direction information obtained by the gyro sensor 52, and after the correction. The current position information is supplied to the recording device 13A. The car navigation system 41 calculates the current position based on the past position information, the history of vehicle speed information, the history of travel direction information, and the like even when the current position information cannot be obtained by the GPS receiver 12A.
[0083]
In addition, the car navigation system 41 supplies the trigger signal from the GPS receiver 12A to the platform circuit 11 as it is, and when the current position information cannot be obtained by the GPS receiver 12A, the car navigation system 41 triggers when calculating the current position. A signal is supplied to the platform circuit 11.
[0084]
Since other operations are the same as those in the second embodiment, description thereof is omitted.
[0085]
In addition to the above, the time interval for calculating the current position by the car navigation system 41 may be adjusted according to the vehicle speed obtained from the vehicle speed pulse.
[0086]
As described above, according to the third embodiment, in addition to the effects of the second embodiment, the car navigation system 41 includes the GPS receiver 12A, the vehicle speed pulse sensor 51, and the gyro sensor 52. Even if the reception state of the signal is temporarily poor, the current position can be accurately measured, and consequently, the radio wave state at each point can be accurately measured.
[0087]
Further, according to the third embodiment, the car navigation system 41 outputs a trigger signal according to a predetermined schedule even when the signal from the GPS satellite is interrupted for a predetermined time or more, so that the car navigation system is used. Thus, even if the reception state of the signal from the GPS satellite is temporarily poor, the radio wave state at each point can be continuously measured according to a predetermined schedule while making the device inexpensive.
[0088]
Embodiment 4 FIG.
The communication state measuring apparatus according to the fourth embodiment of the present invention includes a DGPS (Differential GPS) receiver as a GPS receiver 12A of the communication state measuring apparatus according to the second or third embodiment, and a recording device 13A records the reception state of the correction information when the current position is measured in association with the current position information.
[0089]
In general, a DGPS receiver acquires correction information based on a measurement error obtained by a GPS receiving base station (not shown) by an FM multiplexing method, etc., corrects current position information based on the correction information, and improves measurement accuracy. Improve.
[0090]
Further, the DGPS receiver in the communication state measuring apparatus according to the fourth embodiment supplies the recording apparatus 13A with the reception state of the correction information, that is, whether or not the current position information is corrected using the correction information. When the current position is recorded, it is recorded in association with them.
[0091]
Since the rest is the same as the communication state measuring apparatuses 1A and 1B according to the second or third embodiment, the description thereof is omitted.
[0092]
As described above, according to the fourth embodiment, the DGPS receiver is provided as the position detection means, and the recording device 13A records the reception state of the correction information when the current position is measured in association with the current position information. Therefore, the current position can be measured with high accuracy based on the DGPS, and the communication status at each point in the area can be known in the post-processing in consideration of the reception status of the DGPS correction information.
[0093]
Figure 8, Through3 is a block diagram showing a configuration of a communication state analysis device 2. FIG.
[0094]
In the communication state analysis apparatus 2 shown in FIG. 8, a computer 61 is a CPU 71 that executes a program stored in a ROM 72 or an HDD 74, such as a ROM 72 that stores a program or data necessary for startup, or a program or data that is temporarily stored when the program is executed. The apparatus includes a RAM 73 that stores data, an HDD 74 that stores various programs and data, an interface 75 such as a USB that exchanges data with an external device, and a drawing circuit 76 that performs a drawing process on the display 62.
[0095]
The HDD 74 is a recording medium for storing the communication state analysis program 81, the map data 82 in the area of the mobile telephone system, the measurement data 83 of the radio wave state in the area, and the like.
[0096]
Among these, the communication state analysis program 81 is based on the measurement data 83, the position specifying means for specifying the position where the predetermined characteristic value indicating the radio wave condition satisfies the predetermined condition, and the position specifying means. This is a program for causing the computer 61 to function as position display control means for displaying on the map a position where the specified communication state is bad.
[0097]
In addition, the measurement data 83 is a predetermined characteristic indicating position information of each place in the area and a radio wave state at the position when communicating with the base station by a circuit simulating a communication circuit of a mobile telephone. Data that contains a value.
[0098]
The display 62 is a display device as position display means for displaying a position specified by the computer 61 according to the communication state analysis program 81 on a map.
[0099]
  Next, the operation of the above apparatus will be described.. Figure9 is, Through4 is a flowchart for explaining the operation of the communication state analysis device 2.
[0100]
First, the CPU 71 of the computer 61 acquires the measurement data 83 from, for example, the communication state measuring apparatus 1 described above (FIG. 1) according to the communication state analysis program 81 (step S1). At this time, for example, the computer 61 acquires the measurement data 83 from the communication state measurement apparatuses 1, 1A, 1B via the interface 75 and stores it in the HDD 74 as shown in FIG. Alternatively, the computer 61 drives the recording medium 21 detached from the communication state measuring devices 1, 1A, 1B by a recording medium driving device (not shown) and reads, for example, measurement data 83 as shown in FIGS. It may be. Furthermore, the measurement data 83 may be transmitted to the computer 61 from the communication state measurement apparatuses 1, 1A, 1B using wireless communication or the like.
[0101]
Next, according to the communication state analysis program 81, the CPU 71 of the computer 61 cannot properly receive and demodulate the measurement values (BER value, RSSI value, etc.) of each point in the measurement data 83 from the base station. Each is compared with a predetermined threshold value indicating a boundary whether or not a call is difficult, that is, whether or not a communication state is poor (step S2).
[0102]
Then, the CPU 71 of the computer 61 specifies a position (for example, latitude and longitude) determined to be inferior in the communication state based on the comparison result in step S2 according to the communication state analysis program 81 (step S3).
[0103]
Finally, the CPU 71 of the computer 61 controls the drawing circuit 76 in accordance with the communication state analysis program 81, reads out the map data 82 of the area whose communication state is currently measured and analyzed from the HDD 74, and displays a map image of that area. In addition, an image on which an image indicating a position where the communication state is bad (hereinafter referred to as a bad communication point) is superimposed is displayed on the display 62 (step S4).
[0104]
  FIG., ThroughIt is a figure which shows an example of the map of the area displayed with the communication status analyzer 2, and a communication failure point. In FIG. 10, an image 92 showing three communication failure points is displayed superimposed on an image 91 of the area map.
[0105]
Thereby, the worker can check the communication failure point in the area by looking at the display image, and can adjust the setting of the base station having jurisdiction over the area.
[0106]
Furthermore, when the reception state of the signal from the GPS satellite and the reception state of the correction information for DGPS are also recorded in the measurement data 83 as described in the second to fourth embodiments, the CPU 71 According to the state analysis program 81, an image indicating a position where the reception state of these signals and information is bad may be further superimposed and displayed.
[0107]
Further, a GPS measurement error of the communication failure point is obtained based on the reception state, and the size, color, figure, etc. of the image 92 indicating the communication failure point is changed according to the measurement error of the communication failure point. It may be.
[0108]
  As above,Predetermined information indicating the position of each location in the area of the mobile telephone system and the radio wave state when the computer 61 communicates with the base station using a circuit simulating the communication circuit of the mobile telephone at that position. Based on the characteristic value, a communication failure point whose characteristic value satisfies a predetermined condition is specified, and the display 62 displays the communication failure point specified by the computer 61 on a map. Thereby, even if there are a plurality of communication failure points in the area, they can be easily visually recognized, and a position where the communication state in the area of the mobile telephone system is bad can be found in a low cost and in a short time.
[0109]
  Also, DeSince the display 62 displays on the map the reception state of the signal from the GPS satellite when the characteristic value is measured, the positioning accuracy of each point such as a communication failure point in the area can be easily visually confirmed.
[0110]
  further, DeSince the display 62 displays the reception state of the correction information for DGPS when the characteristic value is measured on the map, the positioning accuracy of each point such as a communication failure point in the area can be easily visually confirmed.
[0111]
In the second to fourth embodiments, the trigger signal is generated in synchronization with the C / A code used for the measurement of the distance to the GPS satellite. When the above signal is used, a trigger signal is generated in synchronization with the signal.
[0112]
【The invention's effect】
  According to the present invention, a communication state measuring apparatus and a communication state measuring method capable of accurately finding a position having a bad communication state in an area of a mobile telephone system at a low cost and in a short time.The lawObtainable.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a communication state measuring apparatus according to Embodiment 1 of the present invention.
FIG. 2 is a diagram showing an example of a format of measurement data recorded on a recording medium of the communication state measurement device shown in FIG.
FIG. 3 is a diagram illustrating an example of a movement locus of the communication state measurement apparatus illustrated in FIG. 1;
FIG. 4 is a block diagram showing a configuration of a communication state measuring apparatus according to Embodiment 2 of the present invention.
5 is a block diagram illustrating a configuration example of a GPS receiver in FIG. 4. FIG.
6 is a diagram showing an example of a format of measurement data recorded on a recording medium of the communication state measurement device shown in FIG.
FIG. 7 is a block diagram showing a configuration of a communication state measuring apparatus according to Embodiment 3 of the present invention.
FIG. 8 shows an embodiment of the present invention.InIt is a block diagram which shows the structure of a communication state analyzer.
FIG. 9Of the present inventionEmbodimentInIt is a flowchart explaining operation | movement of a communication state analyzer.
FIG. 10Of the present inventionEmbodimentInIt is a figure which shows an example of the map of the area displayed with the communication status analysis apparatus, and a communication failure point.
[Explanation of symbols]
1,1A, 1B Communication status measuring device
2 Communication state analyzer
11, 11A platform circuit
12, 12A GPS receiver (position detection means)
13, 13A Recording device (recording means)
41 Car navigation system (position detection means)
51 Vehicle speed pulse sensor
52 GyroceneS

Claims (10)

In a communication state measuring device for measuring a communication state with a base station in an area of a mobile telephone system,
A platform circuit that has a circuit that simulates a communication circuit of a mobile telephone, and that measures a predetermined characteristic value indicating a radio wave state when communicating with the base station by the circuit in time series;
A position detector that has a GPS receiver for receiving signals from GPS satellites and detects the current position by the GPS receiver ;
Each predetermined characteristic value measured along the time series by the platform circuit, the reception state of the signal from the GPS satellite with sequentially recorded in association with the above information Symbol position has been the current position detected by the detection means Recording means for recording in association with the current position information ;
A communication state measuring device comprising: Said position detecting means outputs a trigger signal in synchronization with the signal from the GPS satellite,
The recording means records each predetermined characteristic value when the trigger signal is output in association with information on the current position with respect to the time of reception of the signal from the GPS satellite;
The communication state measuring device according to claim 1.   3. The communication state measuring apparatus according to claim 2, wherein the platform circuit measures each predetermined characteristic value when the trigger signal is supplied and supplies the measured characteristic value to the recording unit.   3. The communication state measuring apparatus according to claim 2, wherein the position detecting means outputs a trigger signal in synchronization with any of a C / A code, a P code and a Y code from a GPS satellite.   The position detection means outputs a trigger signal in synchronization with the timing of the code used for measuring the distance to the GPS satellite in any of the code strings of the C / A code, P code and Y code. The communication state measuring device according to claim 4, wherein   3. The communication state measuring apparatus according to claim 2, wherein the position detection unit outputs the trigger signal according to a predetermined schedule even when a signal from a GPS satellite is interrupted for a predetermined time or more.   The said position detection means is a car navigation system which has the said GPS receiver and at least 1 of a vehicle speed pulse sensor and a gyro sensor, The any one of Claims 1-6 characterized by the above-mentioned. Communication state measuring device. The position detection means includes a DGPS receiver that receives correction information and corrects current position information based on the correction information.
  The recording means records the reception state of correction information used for correction of current position information by the DGPS receiver in association with the information of the current position;
  The communication state measuring device according to any one of claims 1 to 7, wherein The position detection means includes a DGPS receiver that receives correction information by FM multiplexing and corrects current position information based on the correction information .
The recording means records the reception state of correction information used for correction of current position information by the DGPS receiver in association with the information of the current position;
The communication state measuring device according to any one of claims 1 to 7 , wherein In a communication state measurement method for measuring a communication state with a base station at various points in an area of a mobile telephone system,
A predetermined characteristic value indicating a radio wave state when communicating with the base station is measured by a circuit simulating a communication circuit of a mobile telephone in time series, and a signal from the GPS satellite is received. Detecting a current position by a GPS receiver ;
And recording in association with the reception state of the signal from the GPS satellite information of the current position with time of each predetermined characteristic value measured along the sequence, sequentially recorded in association with the above information Symbol current position,
A communication state measuring method comprising:

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