JP2653750B2 - Communication quality prediction method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for predicting communication quality in a mobile communication system during operation of the system.

[0002]

2. Description of the Related Art Conventionally, the evaluation of communication quality in a mobile communication system has been performed when the system is constructed. That is, a test radio wave is emitted from the base station, and the mobile station receives the test radio wave. The mobile station collects the received electric field strength of the test radio wave as information while associating it with the position of the mobile station on the road map. This way,
The relationship between the position on the road map and the received electric field strength is obtained. In general, there is a phase relationship between the received electric field strength and the communication quality between the base station and the mobile station. By using this, it is possible to indirectly evaluate the communication quality at each position on the road map.

[0003]

However, the evaluation of the communication quality is performed by measuring the reception electric field strength at each position on the road map and by comparing the reception electric field strength obtained by the measurement with the reception electric field strength-communication quality correlation. This is an evaluation performed by referring to. That is, indirect evaluation of communication quality. Therefore, it is extremely difficult to predict the communication quality in the system more realistically, for example, taking into account weather conditions during communication. Further, the evaluation of the communication quality cannot be performed once the system shifts to operation.

[0004] The present invention has been made to solve the above problems, and enables the evaluation of communication quality in an operating mobile communication system.
It is an object of the present invention to make this evaluation a direct evaluation and to make it possible to predict communication quality in consideration of weather conditions.

[0005]

In order to achieve the above object, the present applicant proposes a communication quality prediction database construction method, a communication quality prediction method, and a mobile communication system having the following configurations.

First, a method for constructing a database for communication quality prediction according to the present invention provides a mobile communication system having a base station and a predetermined number of mobile stations, wherein the position of the mobile station is changed while the position of the mobile station is changed. It is characterized in that quality information on communication quality and position information indicating the position of a mobile station are collected, and a database on the relationship between the collected quality information and position information is constructed using the weather conditions at the time of collection as parameters.

[0007] A communication quality prediction method according to the present invention comprises:
By referring to the database constructed by the method of the present invention with position information indicating the position of the mobile station on the expected route, the distribution of communication quality on the expected route is predicted using weather conditions as parameters. It is characterized by the following.

A mobile communication system according to the present invention has a base station and a predetermined number of mobile stations, and a measurement uplink for transmitting a signal from the mobile station to the base station between the base stations. A downlink channel for measurement for transmitting a signal from the channel and the base station to the mobile station is provided, and the mobile station includes means for detecting its own position and generating position information,
Means for the base station and the mobile station to transmit and receive the test transmission signal via the measurement uplink channel and / or the measurement downlink channel, respectively, and the test transmission received via the measurement uplink channel or the measurement downlink channel. Means for generating quality information relating to communication quality between the base station and the mobile station based on the signal; collecting the quality information together with the position information while changing the position of the mobile station; and accumulating weather conditions as parameters. Means for predicting the distribution of communication quality on the planned movement route by referring to the database and the information on the database by position information indicating the position of the mobile station on the planned movement route, using weather conditions as parameters. , Is provided.

The method for constructing a communication quality prediction database according to the present invention includes the following four types of methods classified according to the method of collecting quality information and position information.

First, in both the first method and the second method, a measurement uplink channel for transmitting a signal from a mobile station to a base station and a base station to a mobile station are provided between the base station and the mobile station. A method is provided in which a downlink channel for measurement for transmitting a signal is provided, and as quality information, a bit error rate combining the uplink channel for measurement and the downlink channel for measurement and / or an error characteristic obtained by analyzing the bit error rate is collected. is there.

The first method is based on such a premise that a test transmission signal is transmitted from a base station to a mobile station, and the mobile station receiving the test transmission signal indicates a position indicating its own position. Information is added to this test transmission signal and returned to the base station,
The base station that has received the test transmission signal from the mobile station separates the position information from the test transmission signal, and compares the separated test transmission signal with the test transmission signal transmitted to the mobile station. By obtaining the bit error rate, quality information and position information are collected and a database is constructed on the base station side.

According to the second method, the mobile station detects its own position and generates position information under the same premise as the first method, while transmitting the test transmission from the mobile station to the base station. The base station that transmits the signal and receives the test transmission signal from the mobile station returns this test transmission signal to the mobile station, and the mobile station that receives the test transmission signal returns the test received from the base station. By comparing the transmission signal for use with the test transmission signal transmitted to the base station and calculating the bit error rate, the quality information and the position information are collected and a database is constructed on the mobile station side. I do.

According to a third method, a measurement downlink channel for transmitting a signal from the base station to the mobile station is provided between the base station and the mobile station, and the bit error rate and the bit error rate in the measurement downlink channel are provided as quality information. And / or collecting error characteristics obtained by analyzing this.

According to a third method, a test transmission signal is transmitted from a base station to a mobile station under such a premise, and the mobile station receiving the test transmission signal is transmitted from the base station. While generating the same local signal as the test transmission signal,
The transmission signal for test received from the base station is compared with the local signal to determine the bit error rate, whereby quality information and location information are collected and a database is constructed on the mobile station side.

According to a fourth method, a measurement uplink channel for transmitting a signal from the mobile station to the base station is provided between the base station and the mobile station, and the bit error rate and the bit error rate in the measurement uplink channel are provided as quality information. And / or collecting error characteristics obtained by analyzing this.

The fourth method is based on such a premise that the mobile station transmits a test transmission signal with position information added to the base station, and the base station that has received the test transmission signal transmits the test transmission signal to the base station. Generates the same local signal as the test transmission signal transmitted from the station, separates the location information from the test transmission signal received from the mobile station, and bit-compares the separated test transmission signal with the local signal. By obtaining the bit error rate, quality information and position information are collected and a database is constructed on the base station side.

The method for constructing a database for communication quality prediction according to the present invention is further characterized in that information on the contents of the database can be exchanged. That is, the content of the database constructed on the base station side in the first or fourth method is as follows:
It is transmitted to the mobile station side, and a database having the same contents is constructed on the mobile station side. Further, the content of the database constructed on the mobile station side in the second method or the third method is transmitted to the base station side, and the same content database is constructed on the base station side.

The above-mentioned database is preferably a database in which quality information is stored on a map using weather conditions as parameters. Further, when predicting the communication quality, if the distribution of the communication quality of the mobile station on the planned movement route is discretely obtained along the planned movement route in the database, a predetermined predetermined value which is on the planned movement route and close to the predetermined movement route is obtained. It is preferable that the quality information at the number of positions is referred to from the database, and interpolation is performed based on the quality information, so that the distribution of the communication quality on the expected movement route is predicted using the weather condition as a parameter.

[0019]

According to the communication quality prediction database construction method of the present invention, first, quality information and position information are collected. The quality information is information on communication quality between the base station and the mobile station, for example, a bit error rate and an error characteristic obtained by analyzing the bit error rate. The position information is information indicating a position of the mobile station. This collection is performed while changing the position of the mobile station. Therefore, by such a collection process, a database relating to the relationship between quality information and position information is constructed as a database or the like in which quality information is accumulated on a map. This database is a database constructed using the weather conditions at the time of collection as parameters.

Therefore, in the present invention, by referring to the database constructed in this way, it is possible to predict the communication quality in the operating mobile communication system in consideration of weather conditions. That is,
In the communication quality prediction method of the present invention, the database constructed by the above-described method is referred to by the position information indicating the position of the mobile station on the planned movement route, whereby the communication quality of the communication quality on the planned movement route is determined. A distribution is obtained. The communication quality distribution is obtained as a communication quality distribution using weather conditions as parameters since the database is a database using weather conditions as parameters. Therefore, in comparison with the conventional case where the communication quality is indirectly evaluated using the measured reception field strength and the reception field strength-communication quality correlation, more realistic and accurate, for example, weather conditions are also considered. , It is possible to predict the communication quality. In addition, since it is not necessary to collect quality information and the like prior to the operation of the system, it is possible to predict the communication quality as needed during the operation.

Further, the mobile communication system according to the present invention comprises:
A system suitable for implementing such a communication quality prediction database construction method and communication quality prediction method is provided. That is, in the mobile communication system according to the present invention, an uplink channel for measurement and a downlink channel for measurement are provided between the base station and the mobile station. The uplink channel for measurement and the downlink channel for measurement are channels for transmitting signals from the mobile station to the base station or from the base station to the mobile station, respectively. The base station and / or the mobile station transmits and receives the test transmission signal via the measurement uplink channel and / or the measurement downlink channel. The station that has received the test transmission signal (either or both of the base station and the mobile station) generates quality information relating to the communication quality between the base station and the mobile station based on the received test transmission signal. On the other hand, the mobile station has means for detecting its own location and generating location information. The quality information and position information obtained in this way are collected while changing the position of the mobile station, and are stored on a database using weather information as a parameter. The base station and / or the mobile station refers to the information on the database based on the position information indicating the position of the mobile station on the planned travel path, and determines the distribution of communication quality on the planned travel path as a parameter for weather conditions. To predict. As described above, the present invention provides a system suitable for implementing the above-described communication quality prediction database construction method and communication quality prediction method.

In the present invention, the above-mentioned database can be constructed on the base station side or on the mobile station side. In addition, the collection of the quality information and the position information can be performed using both the above-described measurement uplink channel and measurement downlink channel, or can be performed using any one of them. The first to fourth methods described above classify aspects of the communication quality prediction database construction method according to the present invention from such a viewpoint.

First, in the first and second methods, both the uplink channel for measurement and the downlink channel for measurement are used at least for collecting quality information. That is,
Since the quality information is evaluated and collected by transmitting the signal through both the measurement uplink channel and the measurement downlink channel, the quality information obtained by the first method and the second method is It is the bit error rate of the uplink channel and the measurement downlink channel together or an error characteristic obtained by analyzing the bit error rate.

The difference between the first method and the second method is that a database constructed by collecting quality information and location information is constructed on the base station side or on the mobile station side. is there.

In the first method, when collecting quality information and location information, first, a test transmission signal is transmitted from the base station to the mobile station. This test transmission signal is received by the mobile station. In response to receiving the test transmission signal, the mobile station adds position information indicating its own position to the test transmission signal and returns it to the base station. The base station
When a test transmission signal is received from the mobile station, position information indicating the position of the mobile station is separated from the test transmission signal, and bit comparison is performed to determine a bit error rate. The target of the bit comparison is the test transmission signal received from the mobile station and the test transmission signal transmitted to the mobile station.
That is, the base station evaluates how many bit errors have occurred in the test transmission signal received from the mobile station with respect to the test transmission signal transmitted to the mobile station. Therefore, in this method, a database is constructed on the base station side.

In the second method, first, a mobile station detects its own position and generates position information. The mobile station transmits a test transmission signal to the base station in parallel with this processing. Upon receiving the test transmission signal, the base station returns the test transmission signal to the mobile station. Upon receiving the test transmission signal from the base station, the mobile station compares the test transmission signal with the test transmission signal previously transmitted to the base station. That is, it evaluates how many bit errors have occurred due to transmission of the test transmission signal via the measurement uplink channel and the measurement downlink channel.
Therefore, in the second method, a database is constructed on the mobile station side.

In the third method, a downlink channel for measurement is used for collecting quality information. In other words, a bit error occurring when a signal is transmitted from the base station to the mobile station is evaluated as a bit error rate in the downlink channel for measurement or an error characteristic obtained by analyzing the bit error rate.

Therefore, in the third method, a test transmission signal is transmitted from the base station to the mobile station, and the test transmission signal is received by the mobile station. The mobile station
Upon receiving the test transmission signal, the test transmission signal is
The bit error rate is determined by comparing the bit with a local signal generated inside the bit signal. The local signal is the same signal as the test transmission signal transmitted from the base station. Therefore,
By this bit comparison, a bit error of the received test transmission signal with respect to the test transmission signal transmitted from the base station,
That is, the bit error in the measurement downlink channel is evaluated, and the database is constructed on the mobile station side. In this method, unlike the first and second methods described above, the communication quality is evaluated only by using the measurement downlink channel. Therefore, the device configuration necessary to realize this method is the first and second methods. A simple method is sufficient as compared with the second method.

In the fourth method, when collecting quality information, an uplink channel for measurement is used. That is, a bit error occurring when a signal is transmitted from the mobile station to the base station is evaluated as a bit error rate in an uplink channel for measurement or an error characteristic obtained by analyzing the bit error rate.

Therefore, in the fourth method, a test transmission signal to which position information is added is transmitted from the mobile station to the base station. Upon receiving the test transmission signal from the mobile station, the base station separates the position information and compares the test transmission signal with the internally generated local signal.
The local signal is the same signal as the test transmission signal transmitted from the mobile station. Therefore, this bit comparison is performed to evaluate how many bit errors have occurred in the test transmission signal received from the mobile station. Is equivalent to Since the bit error rate obtained by this bit comparison is used in the construction of the above-mentioned database, in this method, the database is constructed on the base station side. In this method, as in the third method, a simple device configuration for realizing the method is sufficient.

Further, in the present invention, the contents of the database constructed on the base station side or the mobile station side are transmitted to the mobile station side or the base station side, respectively. , A database having the same contents is constructed. That is, since a communication line exists between the base station and the mobile station, information on the database can be exchanged via the communication line.

Further, when the above-mentioned database is a database in which quality information is accumulated on a map using weather conditions as parameters, processing such as display of a map on which quality information is superimposed can be performed by referring to the information on this database. It becomes possible. In addition, when predicting the distribution of communication quality on the planned movement route of the mobile station, if the distribution of communication quality is discretely obtained along the planned route on the database, a predetermined number of adjacent positions are determined. By performing the interpolation processing with reference to the information, it is possible to appropriately predict the distribution of the communication quality at an arbitrary position.

[0033]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows an apparatus configuration of a mobile communication system according to one embodiment of the present invention. The mobile communication system shown in FIG. 1 includes a base station 100 built at a predetermined position and an in-vehicle mobile station 20 mounted on a vehicle such as an automobile.
This is a system for performing wireless communication with the “0”. In this figure, a channel for transmitting a signal from base station 100 to in-vehicle mobile station 200 is shown as downlink channel 300, and a channel for transmitting a signal from in-vehicle mobile station 200 to base station 100 is an uplink channel. It is shown as 400.

The base station 100 includes a transmitting / receiving apparatus 102,
It comprises a bit error rate / error characteristic measuring device 104, a weather condition input device 106, a database 108, and a communication quality predicting device 110. The transmission / reception device 102 has a function of transmitting a signal to the in-vehicle mobile station 200 via the downlink channel 300 and a function of receiving a signal transmitted from the in-vehicle mobile station 200 via the uplink channel 400. As will be described later, the bit error rate / error characteristic measuring device 104
This is a device for measuring the bit error rate and the error characteristics of the communication line composed of both the channels 300 and 400 together or the uplink channel 400. Therefore, the bit error rate / error characteristic measuring device 104 transmits a pseudo-random signal (a signal modulated by a predetermined code sequence and spread to such an extent that the spectrum can be regarded as noise) from the transmitting / receiving device 102 as necessary. And a function of obtaining a bit error rate and an error characteristic based on a pseudo-random signal received by the transmission / reception device 102. The weather condition input device 106 includes, for example,
It may be configured as an input device manually operated by a user, or may be configured as a weather observation device or a weather observation database. The weather condition input device 106 is a device that gives the weather condition at that time to the bit error rate / error characteristic measuring device 104 when measuring the bit error rate or the error characteristic in the communication line. Database 10
Reference numeral 8 denotes a weather condition input by the weather condition input device 106 while associating the bit error rate and the error characteristic measured by the bit error rate / error characteristic measurement device 104 with the position of the vehicle-mounted mobile station 200 at the time of measurement. Is a database that stores as a parameter. As shown in FIG. 6, which will be described in more detail later, the data is stored in the database 108 at positions X _a1 , X _a2 ,... ) Q _a1 , Q _a2 ,... _Are stored as a pair on a road map. In FIG. 6, these positions X _a1 , X _a2 ,... _Are set to positions on the road, which is the planned movement route of the vehicle-mounted mobile station 200. The communication quality prediction device 110 predicts the communication quality at an arbitrary position (for example, the current position) of the vehicle-mounted mobile station 200 on the planned movement route by referring to the data on the database 108.

Similarly to the base station 100, the on-vehicle mobile station 200 includes a transmission / reception device 202, a bit error rate / error characteristic measurement device 204, a weather condition input device 206, a database 208, and a communication quality prediction device 210. I have. The functions of these members are the same as those on the base station 100 side, and a description thereof will be omitted. Further, the on-vehicle mobile station 200 includes, besides these members, the on-vehicle mobile station 2.
00 is provided with a position detecting device 212 that detects a position on the road map of 00 and supplies the result to the bit error rate / error characteristic measuring device 204 as position information. Bit error rate / error characteristic measuring device 204 in vehicle-mounted mobile station 200
When the base station 100 constructs the database 108 relating to communication quality, the transmission / reception device 202 transmits the position information obtained by the position detection device 212 to the base station 100, and the in-vehicle mobile station 200 When constructing the database 208 on the side, the database 208 is used together with information on communication quality such as bit error rate / error characteristics and weather conditions as parameters.
To provide location information. The target of measurement by the bit error rate / error characteristic measuring device 204 is the communication quality of the downlink channel 300 and the uplink channel 400 together and the communication quality of the downlink channel 300.

Further, in this embodiment, information exchange between the databases 108 and 208 is possible. That is, the information on the database 108 is transmitted by the transmission / reception devices 102 and 202 as necessary.
0 is transferred and stored on the database 208, or the information on the database 208 is transferred and stored on the database 108 via the upstream channel 400. Therefore, whether the communication quality is evaluated on the base station 100 side or the communication quality evaluation is performed on the vehicle-mounted mobile station 200 side, as a result, the database 1 having the same contents is obtained.
08 and 208, the base station 100 and the on-vehicle mobile station 200
Each can be secured.

As a method for constructing the database 108 or 208 required for predicting communication quality in the apparatus configuration shown in FIG. 1, any of the methods shown in FIGS. 2 to 6 can be adopted, for example. Among these methods, the methods shown in FIGS. 2 and 3 are methods for measuring the bit error rate and the error characteristics of a communication line combining the uplink channel 400 and the downlink channel 300, and are shown in FIG. The method shown is performed from the base station 100 side, and the method shown in FIG.
This is a method of transmitting a pseudo random signal as a test transmission signal from the 00 side. 4 is a method of measuring a bit error rate and an error characteristic in the downlink channel 300. In this method, the base station 100 transmits a pseudo-random signal as a test transmission signal. The method shown in FIG. 5 is a method for measuring the bit error rate and error characteristics in the uplink channel 400. In this method, the mobile station 200 transmits a pseudo random signal as a test transmission signal.

First, the method shown in FIG. 2 will be described. In this method, first, the bit error rate / error characteristic measurement device 104 causes the transmission / reception device 102 to transmit the pseudo-random signal A to the vehicle-mounted mobile station 200 via the measurement downlink channel 300a. The measurement downlink channel 300a is a channel used to evaluate a bit error occurring in the downlink channel 300, and a measurement uplink channel 400a described later is an uplink channel 40
This is a channel for evaluating a bit error occurring at 0. The pseudo-random signal A transmitted from the transmitting / receiving apparatus 102 of the base station 100 includes a downlink channel 3 for measurement.
At 00a, some bit errors generally occur. Therefore, the pseudo-random signal A is regarded as a pseudo-random signal B in which a certain bit error has occurred.
00 is received by the transmission / reception device 202.

When receiving the pseudo-random signal B, the transmitting / receiving apparatus 202 adds to the pseudo-random signal B the position information supplied from the position detecting apparatus 212, that is, the information indicating the position of the vehicle-mounted mobile station 200. Above, it transmits to base station 100 side via measurement uplink channel 400a. Generally, some bit error is added to this pseudo random signal B in the measurement uplink channel 400a. The transmission / reception device 102 of the base station 100 receives the signal to which such an error is added, that is, the pseudo random signal C.

Bit error rate / error characteristic measuring device 104
Separates the pseudo-random signal C
Is compared with the pseudo-random signal A used at the time of transmission. Thereby, the bit error rate / error characteristic measuring device 10
4 evaluates bit errors occurring in the measurement downlink channel 300a and the measurement uplink channel 400a, and outputs a bit error rate and an error characteristic obtained by analyzing the bit error rate as a measurement result. That is, the bit error rate / error characteristic measuring apparatus 104 uses the database 108 to store the bit error rate and the error characteristic of the communication channel including the downlink channel 300 and the uplink channel 400 together with the separated position information as information indicating the communication quality. Supply on top. At this time, the bit error rate / error characteristic device 104 inputs a weather condition from the weather condition input device 106, and stores information on the database 108 using the weather condition as a parameter. Such processing is executed while moving the vehicle-mounted mobile station 200. Thereby, the database 108 can be completed for a certain road section, for example.

Next, in the method shown in FIG. 3, first, a pseudo random signal D is transmitted from the transmitting / receiving device 202 of the on-vehicle mobile station 200 to the measurement uplink channel 400a. A certain bit error is added to the pseudo random signal D in the measurement uplink channel 400a,
The transmission / reception device 102 of the base station 100 receives the signal as a pseudo-random signal E. The transmitting / receiving device 102
This pseudo-random signal E is directly returned to the on-vehicle mobile station 200 via the measurement downlink channel 300a. In the measurement downlink channel 300a, a bit error is generally added to the pseudo-random signal E, so that the pseudo-random signal received by the transmission / reception device 202 of the on-vehicle mobile station 200 has a bit error Is added to the pseudo-random signal F. Send /
The receiving device 202 supplies the pseudo-random signal F obtained in this way to the bit error rate / error characteristic measuring device 204.

Bit error rate / error characteristic measuring device 204
Performs a bit comparison between the transmitted pseudo-random signal D and the received pseudo-random signal F, and thereby evaluates a bit error generated in the measurement uplink channel 400a and the measurement downlink channel 300a. That is, the bit error rate indicating the quality of the communication channel including the uplink channel 400 and the downlink channel 300 and the error characteristics obtained by the analysis are supplied to the database 208 as the measurement result. At this time, the bit error rate / error characteristic measuring device 204
Is the in-vehicle mobile station 2 obtained by the position detecting device 212.
The location of 00 is stored in the database 208 in association with the obtained information on the communication quality, and the weather condition input from the weather condition input device 206 is stored as a parameter. This processing is performed in the same manner as in FIG.
To be executed repeatedly.

In the method shown in FIG. 4, first, the bit error rate / error characteristic measuring device 104 of the base station 100 functions as a transmitting unit. That is, the bit error rate / error characteristic measuring device 104 causes the transmitting / receiving device 102 to transmit the pseudo-random signal G. This pseudo random signal G is received by the transmission / reception device 202 of the vehicle-mounted mobile station 200 via the measurement downlink channel 300a. The received pseudo-random signal is a downlink channel 300 for measurement.
Since a certain bit error is generally added in a, the pseudo random signal H is different from the pseudo random signal G.

Bit error rate / error characteristic measuring device 204
Compares the bit of the pseudo-random signal H received by the transmitting / receiving device 102 with the local signal generated inside the bit error rate / error characteristic measuring device 204. This local signal is the same signal as the pseudo random signal G generated in the base station 100. Therefore, by performing such a bit comparison in the bit error rate / error characteristic measuring device 204, a bit error in the measurement downlink channel 300a is evaluated, and as a result, the downlink channel 300
Is obtained as the bit error rate and the error characteristics obtained by analyzing the bit error rate. The bit error rate / error characteristic measuring device 204 associates the information on the obtained communication quality with the position information of the vehicle-mounted mobile station 200 obtained by the position detecting device 212 and is input from the weather condition input device 206. The weather condition is stored as a parameter on the database 208. This process also
It is repeatedly executed while moving the vehicle-mounted mobile station 200.

In the method shown in FIG. 5, first, the bit error rate / error characteristic measuring device 20 of the on-vehicle mobile station 200 is used.
4, the pseudo random signal I is transmitted from the transmission / reception device 202. This pseudo-random signal I includes the position of the vehicle-mounted mobile station 200 detected by the position detection device 212 as position information. That is, the bit error rate / error characteristic measuring device 204
When transmitting the pseudo-random signal A from 2, the position information obtained by the position detecting device 212 is added to this.
The pseudo-random signal I is received as a pseudo-random signal J by the transmission / reception device 102 of the base station 100 via the measurement uplink channel 400a. This pseudo-random signal J includes a bit error generated in the measurement uplink channel 400a.

Transmitting / Receiving Apparatus The pseudo-random signal J received by the receiving apparatus 102 is supplied to the bit error rate / error characteristic measuring apparatus 104, and the position information added on the vehicle-mounted mobile station 200 side is separated. The bit error rate / error characteristic measuring device 104 receives the local signal generated therein, that is, a signal having the same content as the pseudo-random signal I before adding the position information, and the transmitting / receiving device 102, The bit is compared with the pseudo-random signal J from which the position information is separated. What is evaluated by this bit comparison is a bit error that has occurred in the measurement uplink channel 400a.
And the error characteristics obtained by analyzing the bit error rate, which indicates the communication quality of the data. The bit error rate / error characteristic measuring device 104 associates the information related to the communication quality of the uplink channel 400 with the separated position information and uses the weather condition input by the weather condition input device 106 as a parameter as a database 108 Store above. This process is also executed repeatedly while moving the vehicle-mounted mobile station 200.

FIGS. 6 and 7 show the contents of the operation of the communication quality prediction device 110 or 210 in this embodiment.

As shown in FIG. 6, the database 10
8 or 208, the position information and the information on the communication quality are associated on a road map, and the weather condition a is stored as a parameter. In the example of FIG. 6, the positions X _a1 , X _a2 ,... _Are associated with the communication qualities Q _a1 , Q _a2,. Here, a is the communication quality Q _a1 , Q _a2 ,..., That is, the weather condition at the time when the bit error rate and the error characteristic are measured, for example, the condition that the rainfall is 20 mm. As described above, the distribution of the communication quality on the road map is stored as data on the databases 108 and 208 using the weather condition a as a parameter.

The communication quality estimating device 110 or 210 is designed to move the on-vehicle mobile station 200, that is, an arbitrary position X _ai existing on a road section having the ends Xa and Xb.
Of the communication quality XQ _ai is predicted. That is, the positions X _ai-1 and X a near the position X _ai on the road
communication quality Q _ai-1 and Q at _{ai + 1
ai + 1} is called from the database 108 or 208, performs linear interpolation as shown in FIG.
_Find the communication quality XQ _ai at _ai . The communication quality thus determined is used, for example, displayed on a screen of a display device (not shown) together with the map information.

Therefore, according to the present embodiment, the base station 100
The mobile communication station 200 transmits and receives a pseudo-random signal and measures the bit error rate and error characteristics based on the received pseudo-random signal to construct the database 108 or 208. There is no need to evaluate the communication quality prior to the transition, and information about the communication quality can be collected and predicted as needed after the operation transition. This communication quality prediction is not an indirect evaluation using the received electric field strength and the received electric field strength-communication quality correlation, but a measurement downlink channel 3.
Since the bit error rate is obtained by directly evaluating the bit error rate using both or one of the uplink channel 00a and the measurement uplink channel 400a, it is possible to predict the communication quality extremely easily and extremely accurately as compared with the related art. Becomes In addition, since such communication quality prediction is realized, communication between the base station 100 and the on-vehicle mobile station 200 can be performed using a line that provides high communication quality.
That is, when communication is performed using a certain line, if the communication quality fluctuates greatly depending on the position of the on-vehicle mobile station 200, such a line is avoided, and a higher communication quality is stably obtained. The line can be switched to perform communication. Therefore, high quality data communication,
It can be realized with a simple device configuration, and a communication disabled state or the like is unlikely to occur.

Further, according to the present embodiment, the information of the databases 108 and 208 can be exchanged by the communication line (uplink channel 400 and downlink channel 300) provided between the base station 100 and the on-vehicle mobile station 200. If necessary, the communication quality of the communication line can be evaluated and measured by selectively using the methods shown in FIGS. Further, as shown in FIG. 7, since the interpolation is performed, the communication quality can be predicted for an arbitrary position _Xai .

In FIG. 6, a single weather condition a
And a single road section, the effect of the present embodiment is that a large number of weather sections are set as parameters as weather conditions, and that a large number of road sections are set as a traveling route of the vehicle-mounted mobile station 200. It becomes remarkable. Also,
As the interpolation method, an interpolation method other than the linear interpolation may be used. Furthermore, the more the number of data distributed on the planned movement route (road) of the on-vehicle mobile station 200, the better the communication quality prediction accuracy is.

In addition, the present invention is not limited to a system configuration in which a mobile station is mounted on a vehicle.
However, the present invention is not limited to an apparatus having all the measurement functions shown in FIGS. Furthermore, the methods shown in FIGS. 2 to 5 can be combined as appropriate. For example, the pseudo-random signal A in FIG. 2 and the pseudo-random signal G in FIG. 4 can be shared, and the pseudo-random signal D in FIG. 3 and the pseudo-random signal I in FIG. 5 can be shared.

[0055]

As described above, according to the communication quality predicting database construction method according to the present invention, quality information and position information are collected while changing the position of a mobile station, and weather information is collected based on the collected information. Since a database of quality information and location information using conditions as parameters has been constructed, it is possible to directly evaluate and predict the communication quality after the transition of the operation of the mobile communication system. It is possible to execute it. Therefore, accurate communication quality prediction can be executed with an extremely simple device configuration as compared with the related art.

Further, according to the communication quality prediction method of the present invention, the database constructed by the method of the present invention is referred to by the position information indicating the position of the mobile station on the expected route. In addition, it becomes possible to predict the distribution of communication quality on the expected route using weather conditions as parameters.

Further, according to the mobile communication system of the present invention, an uplink channel for measurement and a downlink channel for measurement are provided between the base station and the mobile station, and the mobile station generates position information indicating its position. Since the quality information related to the communication quality is generated based on the test transmission signal received via the measurement uplink channel and / or the measurement downlink channel, the quality information and the position information are collected while changing the position of the mobile station. It is possible to construct a database that is associated with weather conditions, and it is possible to predict the distribution of communication quality of the mobile station on the planned route of travel using the weather conditions as parameters. That is, a system suitable for implementing the communication quality prediction database construction method and the communication quality prediction method according to the present invention can be realized with a relatively simple device configuration.

Further, when a measurement uplink channel and a measurement downlink channel are provided, the bit error rate combined with the measurement downlink channel and / or the error characteristics obtained by analyzing the same are collected as quality information. The quality information can be collected by transmitting and receiving signals between the base station and the mobile station. Further, when a downlink channel for measurement is provided between the base station and the mobile station, and a bit error rate and / or error characteristic in the downlink channel for measurement is collected as quality information, a signal from the base station to the mobile station is transmitted. The transmission makes it possible to collect quality information. Further, when an uplink channel for measurement is provided between the base station and the mobile station, and the bit error rate and / or error characteristics of the uplink channel for measurement are collected as quality information, the collection is performed from the mobile station to the base station. This can be realized by transmitting a signal to a station.

Further, a test transmission signal is transmitted from the base station to the mobile station via the measurement downlink channel, and location information indicating the position of the mobile station is added to the test transmission signal. When returning to the base station side, it is possible to determine the bit error rate by separating the position information from the test transmission signal and comparing the bits of the transmitted test transmission signal and the received test transmission signal, A database can be constructed on the base station side.

In the case where the mobile station generates position information, the mobile station transmits a test transmission signal to the base station, and the base station returns the test transmission signal to the mobile station. In, the bit error rate can be obtained by comparing the bits of the transmitted test transmission signal with the received test transmission signal, and a database can be constructed on the mobile station side.

Further, when a test transmission signal is transmitted from the base station to the mobile station, and the mobile station generates the same local signal as the test transmission signal, the mobile station transmits the received test signal. The bit error rate can be obtained by comparing the bit between the transmission signal and the local signal, and a database can be constructed on the mobile station side.

In addition, when the mobile station transmits a test transmission signal to which the location information is added to the base station, and the base station generates the same local signal as the test transmission signal, In, the bit error rate can be obtained by separating the position information from the received test transmission signal and then comparing the bit with the local signal, thereby making it possible to construct a database on the base station side.

Further, when the content of the database constructed on the base station side or the mobile station side is transmitted to the mobile station side or the base station side, the database having the same content is constructed on both the mobile station side and the base station side. It is possible to do.

Further, when a database in which quality information is stored on a map using weather conditions as parameters is constructed as a database, information on communication quality is displayed on a screen together with the map by referring to the information on the database. Can be provided.

When the communication quality is predicted, the distribution of the communication quality at an arbitrary position on the planned travel route is determined by performing an interpolation operation by referring to the quality information from the database. Can be predicted as a parameter.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an apparatus configuration of a mobile communication system according to one embodiment of the present invention.

FIG. 2 is a diagram illustrating a method of transmitting a test transmission signal from a base station and measuring an error rate and an error characteristic of a communication line including both uplink and downlink.

FIG. 3 is a diagram illustrating a method of transmitting a test transmission signal from a mobile station and measuring an error rate and an error characteristic of a communication line including both uplink and downlink.

FIG. 4 is a diagram illustrating a method of transmitting a test transmission signal from a base station and measuring an error rate and an error characteristic of a downlink communication line.

FIG. 5 is a diagram illustrating a method of transmitting a test transmission signal from a mobile station and measuring an error rate and an error characteristic of an uplink communication line.

FIG. 6 is a diagram showing a communication quality distribution of a designated road section on a road map under weather condition a.

FIG. 7 is a diagram showing a communication quality prediction method by interpolation in this embodiment.

[Explanation of symbols]

REFERENCE SIGNS LIST 100 base station 200 in-vehicle mobile station 102, 202 transmitting / receiving device 104, 204 bit error rate / error characteristic device 106, 206 weather condition input device 108, 208 database 110, 210 communication quality predicting device 212 position detecting device 300 downlink channel 300a Down channel for measurement 400 Up channel 400a Up channel for measurement A to J Pseudo random signals X _a1 , X _a2 , X _a3 ,... X _ai-1 , X _{ai + 1}
Positions at which communication quality was measured Q _a1 , Q _a2 , Q _a3 ,... Q _ai-1 , Q _{ai + 1}
Measured communication quality X _a , X _b Boundary of road section X _ai Arbitrary position related to communication quality prediction XQ _ai Predicted communication quality

Claims (13)

(57) [Claims] 1. A mobile communication system having a base station and a predetermined number of mobile stations, wherein a signal is transmitted from the mobile station to the base station between the base stations.
Channel for measurement and base station to mobile station
Signal measuring downlink channel for transmitting is arranged to, while changing the position of the mobile station, to collect location information indicating the position of the quality information and the mobile station concerning the communication quality between a base station and a mobile station, also , The collected quality information is
Bit error rate for channel and downlink channel for measurement
And / or constructing a database relating to the relationship between the collected quality information and the positional information , which is an error characteristic obtained by analyzing the same, using the weather condition at the time of collection as a parameter. Method. 2. The method according to claim 1, wherein a test transmission signal is transmitted from the base station to the mobile station, and the mobile station receiving the test transmission signal indicates its own position.
Attach location information to this test transmission signal and return to base station
The base station that has received the test transmission signal from the mobile station performs this test.
In addition to separating the position information from the test transmission signal,
The test transmission signal and the test transmission signal transmitted to the mobile station are
By obtaining the bit error rate by comparing the bits, the quality information and the position information are collected and the data
A method wherein the base is established on the base station side. 3. The method according to claim 1, wherein the mobile station detects its own position and generates position information.
Then, the base station that transmitted the test transmission signal from the mobile station to the base station and received the test transmission signal from the mobile station performs this test.
The test transmission signal is returned to the mobile station, and the mobile station receiving the test transmission signal returns from the base station.
The test transmission transmitted to the base station from the received test transmission signal
In and the child to determine the bit error rate and signal and a bit comparison
Ri, the data acquisition of the quality information and the position information are performed
A method wherein the base is established on the mobile station side. 4. A mobile station having a base station and a predetermined number of mobile stations.
In a mobile communication system, a signal is transmitted from a base station to a mobile station between the base station and the mobile station.
A downlink channel for measurement is provided for communication between the base station and the mobile station while changing the position of the mobile station.
Quality information on the communication quality and location information indicating the location of the mobile station.
Information, and the collected quality information is
Analyzing the bit error rate in the channel and / or
Error characteristics that can be obtained from a database containing the relationship between the collected quality information and location information.
A source using the weather conditions at the time of collection as parameters
Method of constructing communication quality prediction database
Law. 5. The method according to claim 4, wherein a test transmission signal is transmitted from the base station to the mobile station, and the mobile station receiving the test transmission signal transmits the test transmission signal from the base station.
Generating the same local signal as the test transmission signal
The test transmission signal received from the base station is
By comparing the data and the bit error rate, the quality information and the position information are collected and the data
A method wherein the base is established on the mobile station side. 6. A mobile station having a base station and a predetermined number of mobile stations.
In a mobile communication system, a signal is transmitted from a mobile station to a base station between the base station and the mobile station.
A measurement uplink channel is provided for performing communication between the base station and the mobile station while changing the position of the mobile station.
Quality information on the communication quality and location information indicating the location of the mobile station.
Information collected and quality information collected
Analyzing the bit error rate in the channel and / or
Error characteristics that can be obtained from a database containing the relationship between the collected quality information and location information.
A source using the weather conditions at the time of collection as parameters
Method of constructing communication quality prediction database
Law. 7. A test transmission according to claim 6, wherein the mobile station adds location information to the base station.
The base station that has transmitted the radio signal and received the test transmission signal transmits from the mobile station.
Generating the same local signal as the test transmission signal
The location information from the test transmission signal received from the mobile station.
After being separated, the test transmission signal after separation is
By collecting the quality information and the location information by comparing
A method wherein the base is established on the base station side. 8. The method according to claim 2, wherein the contents of the database constructed in the base station are stored in the mobile station.
And the mobile station has the same database
A method characterized by being built. 9. The method according to claim 3, wherein the contents of the database constructed on the mobile station side are stored in the base station side.
Transmitted to the base station, and the base station
A method characterized by being built. 10. The method according to claim 1, wherein said database is a map using weather conditions as parameters.
It is a database that stores quality information on top
And how. 11. The method according to claim 1, wherein
The built database is stored on the mobile station's planned route.
By referring to the location information indicating the location
The distribution of communication quality on the planned route
Communication product characterized by predicting the condition as a parameter
Quality prediction method. 12. The method according to claim 11, wherein the distribution of the communication quality of the mobile station on the expected route is determined by
Discretely along the expected route on the database
If there is a certain
Look up the quality information at the number position from the database,
By performing interpolation based on these, it is possible to
Distribution of communication quality in
Communication quality prediction method characterized by predicting the communication quality. 13. A mobile station comprising a base station and a predetermined number of mobile stations.
In a mobile communication system, a signal is transmitted from a mobile station to a base station between the base station and the mobile station.
Channel for measurement and base station to mobile station
A downlink channel for measurement for transmitting signals is provided, and the mobile station detects its own location and generates location information
Means, wherein the base station and the mobile station communicate via the measurement uplink channel and / or the measurement downlink channel , respectively.
Means for transmitting and receiving a test transmission signal and receiving via a measurement uplink channel or a measurement downlink channel.
Between the base station and the mobile station based on the received
Means for generating quality information relating to communication quality, and changing the position of the mobile station,
Collect with information and store weather conditions as parameters
Database and information on the database are stored on the mobile station's planned route.
By referring to the location information indicating the location
The distribution of communication quality on the planned route
Means for predicting a condition as a parameter , the mobile communication having a communication quality prediction function.
system.