JP2020136876A - Base station selection device and base station selection method - Google Patents

Abstract

To allow a base station to be selected in consideration of a change in communication environment of a mobile station and a base station when selecting a base station with which the mobile station is going to communicate from a plurality of base stations.SOLUTION: A base station selection device 10 includes a quality measuring unit 11, a parameter measuring device 13, a machine learning device 15, and a selection unit 17. The quality measuring unit 11 measures communication quality between a mobile station 1 and a base station for each base station 5 or 7. The parameter measuring device 13 measures values of one or more parameters whose values fluctuate according to a change in communication environment between the mobile station 1 and the base station 5 or 7. The machine learning device 15 machine-learns a relation between the values of the one or more parameters and a base station to be selected based on measurement results by the quality measuring unit 11 and the parameter measuring device 13. The selection unit 17 selects the base station with which the mobile station is going to communicate based on the machine-learned relation and the values of the one or more parameters measured at the time of base station selection.SELECTED DRAWING: Figure 2

Description

The present invention relates to a base station selection device and a base station selection method for selecting a base station that communicates with a mobile station from a plurality of base stations.

The mobile station is provided in a mobile device (for example, a vehicle). The mobile station wirelessly communicates with the base station outside the mobile device. A plurality of base stations are provided, and a plurality of base station antennas provided in each of the plurality of base stations are arranged at intervals. The mobile station communicates with any of these base stations.

A technique for switching a base station with which a mobile station communicates has been developed based on the communication quality between the mobile station and the base station (for example, Patent Document 1). For example, the communication quality between a base station and a mobile station is measured, and when the measured communication quality value becomes equal to or less than a threshold value, the base station with which the mobile station communicates is switched to another base station. The communication quality is, for example, the intensity of radio waves received by the mobile station antenna (hereinafter referred to as mobile station antenna) from the base station antenna (hereinafter referred to as base station antenna).

Japanese Unexamined Patent Publication No. 2016-86305

At first glance, the method of switching base stations based on the threshold value as described above seems to be rational and effective. However, in this method, the base station may not actually switch smoothly. This is because the communication environment between the mobile station antenna and the base station antenna changes from moment to moment. For example, radio waves from a base station antenna are reflected by radio wave obstacles and reach the mobile station antenna as multiple radio waves at different times, and as a result, these radio waves interfere with each other to receive radio waves. The strength of is fluctuating. Since the interference state of such radio waves changes from moment to moment, the antenna cannot be switched smoothly only by determining whether the communication quality is below the threshold value. In the example, the mobile station antenna approaches another base station antenna while communicating with one base station antenna, but the communication is interrupted without smoothly switching to the other base station antenna, and then the communication is interrupted. It was switched to the other base station antenna.

Therefore, an object of the present invention is to provide a technique capable of selecting a base station with which a mobile station communicates in consideration of changes in the communication environment between the mobile station and the base station.

In order to achieve the above object, the base station selection device according to the present invention is a device that selects a base station with which a mobile station communicates from a plurality of base stations.
For each base station, a quality measurement unit that measures the communication quality between the mobile station and the base station,
A parameter measuring device that measures the values of one or more parameters whose values fluctuate according to changes in the communication environment between the mobile station and the base station.
A machine learning device that machine-learns the relationship between the values of one or more parameters and a base station to be selected based on the measurement results of the quality measurement unit and the parameter measurement device.
It includes a selection unit that selects the base station with which the mobile station communicates based on the machine-learned relationship and the value of the one or a plurality of parameters measured at the time of selecting the base station.

Further, in order to achieve the above object, the base station selection method according to the present invention is a method of selecting a base station with which a mobile station communicates from a plurality of base stations.
(A) For each base station, the communication quality between the mobile station and the base station is measured.
(B) Measure the values of one or more parameters whose values fluctuate according to changes in the communication environment between the mobile station and the base station.
(C) Based on the measurement results of the above (A) and the above (B), the relationship between the values of the one or more parameters and the base station to be selected is machine-learned.
(D) The base station with which the mobile station communicates is selected based on the machine-learned relationship and the value of the one or more parameters measured at the time of selecting the base station.

According to the present invention, it is possible to select a base station in consideration of changes in the communication environment.

It is a schematic plan view which shows an example of the communication system to which the base station selection apparatus by embodiment of this invention is applied. It is a block diagram which shows the structure of the base station selection apparatus by embodiment of this invention. It is a top view for explaining a parameter. It is another plan view for explaining a parameter. A two-dimensional coordinate system representing training data used for machine learning is shown. It is a flowchart which shows the base station selection method by embodiment of this invention. It is a top view which shows the outline of a container terminal. It is a side view of the automatic transport vehicle which is an example of a moving device.

Embodiments of the present invention will be described with reference to the drawings. The common parts in each figure are designated by the same reference numerals, and duplicate description will be omitted.

(Communication system configuration)
FIG. 1 is a schematic plan view showing an example of a communication system 100 to which the base station selection device 10 according to the embodiment of the present invention is applied. The communication system 100 includes a mobile station 1, a command device 3, and a plurality of base stations 5 and 7.

The mobile station 1 is provided in the mobile device 20 and receives a command signal from the command device 3 via the base stations 5 and 7. The mobile station 1 includes a mobile station antenna 1a and a signal input unit 1b. The mobile station antenna 1a receives a command signal transmitted as a radio wave from the base station 5 or 7. The signal input unit 1b inputs the command signal received by the mobile station antenna 1a to the control unit 9 provided in the mobile device 20. Based on the input command signal, the control unit 9 controls the mobile device 20 so that the mobile device 20 moves within a predetermined area A to perform work. The moving device 20 may be a vehicle (for example, an unmanned vehicle) or a robot.

The mobile station 1 transmits the state related to the mobile device 20 to the base stations 5 and 7. The base stations 5 and 7 transmit the received state to the command device 3. The state relating to the mobile device 20 is detected by, for example, an appropriate sensor provided in the mobile device 20, and includes at least one of the position of the mobile device 20 and the progress state of the work performed by the mobile device 20.

The work performed by the moving device 20 based on the command signal may be the work of transporting the object from the transport source to the transport destination. In the first example, in a state where the moving device 20 is located at the transport source, the object is placed on the moving device 20 (for example, a table on the moving device 20) from a gripping device (for example, a crane 23 described later) that grips the object. Then, the moving device 20 moves to the transport destination, and at the transport destination, the object placed on the moving device 20 is gripped by the gripping device (for example, the crane 25 described later) and delivered to the gripping device. In the second example, with the moving device 20 located at the transport source, the gripping device provided in the moving device 20 grips and picks up the object at the transport source, and the moving device 20 moves to the transport destination and transports the object. First, the object gripped by the gripping device is released and delivered to the transport destination.

The command device 3 generates the above-mentioned command signal. For example, the command device 3 generates a command signal based on a state related to the mobile device 20 from the mobile station 1 (for example, the progress state of the above work) and a work plan stored in advance in itself. The command device 3 transmits the generated command signal to the plurality of base stations 5 and 7. The command device 3 is located outside the mobile device 20 and at a position away from the base stations 5 and 7. The command signal from the command device 3 is transmitted as a radio wave from a plurality of base stations 5 and 7. The mobile station antenna 1a receives a command signal transmitted from the base station 5 or 7 selected by the base station selection device 10 among the plurality of base stations 5 and 7, as will be described later. This command signal may include command position information indicating a position where the moving device 20 should move. In this case, when the mobile station 1 receives the command signal, the mobile device 20 moves to the position indicated by the command position information included in the command signal under the control of the control unit 9. In either of the above-mentioned first example and the second example, the command signal may include the command position information, and the command position information indicates the position of the above-mentioned transport source or transport destination. In this case, in the second example, the command signal includes the command position information and the operation command, and under the control of the control unit 9, the moving device 20 moves to the position of the transport source or the transport destination indicated by the command position information, and the said. According to the operation command, the gripping device of the moving device 20 may perform an operation of gripping or releasing the object at the transport source or the transport destination.

The base stations 5 and 7 are provided at positions where the command signal from the command device 3 can be received. Each base station 5 or 7 receives a command signal from the command device 3. Each base station 5 or 7 includes base station antennas 5a and 7a and transmission circuits 5b and 7b. In each of the base stations 5 and 7, the transmission circuits 5b and 7b supply electric power to the base station antennas 5a and 7a so that the base station antennas 5a and 7a transmit the received command signal by radio waves. The number of base stations may be two or more.

The plurality of base station antennas 5a and 7a each of the plurality of base stations 5 and 7 are arranged at intervals so as to be able to communicate with the mobile station antenna 1a in the predetermined area A. Each of the base stations 5 and 7 can communicate with the mobile station antenna 1a located within the communicable area of the base stations 5 and 7. The communicable area of each of the base stations 5 and 7 is affected by the radio interference 2 and other factors in the area A. The communicable areas of the base station antennas 5a and 7a may partially overlap each other. In the present application, the radio wave obstacle changes the traveling direction of the radio wave (for example, reflects the radio wave) or absorbs the radio wave.

A frequency for communication is set in each of the base stations 5 and 7, and this frequency (hereinafter referred to as a set frequency) may be different for each of the base stations 5 and 7. In this case, the plurality of base stations 5 and 7 transmit the above-mentioned command signal from the base station antennas 5a and 7a with radio waves having different set frequencies. In the mobile station 1, the mobile station antenna 1a receives radio waves transmitted from the plurality of base station antennas 5a and 7a, respectively, and the signal input unit 1b receives the radio waves received by the mobile station antenna 1a, which will be described later. A command signal of a radio wave having the same frequency as the set frequency of the base station 5 or 7 selected by the base station selection device 10 is extracted, and the extracted command signal is output to the control unit 9.

(Configuration of base station selection device)
FIG. 2 is a block diagram showing a configuration of a base station selection device 10 according to an embodiment of the present invention. The base station selection device 10 selects a base station with which the mobile station 1 communicates from a plurality of base stations 5 and 7. The base station selection device 10 includes a quality measurement unit 11, a parameter measurement device 13, a machine learning device 15, and a selection unit 17.

The quality measurement unit 11 measures the communication quality between the mobile station antenna 1a and the base station for each of the base stations 5 and 7. In one example, this communication quality is, but is not limited to, the intensity of radio waves received by the mobile station antenna 1a from the base stations 5 and 7 (that is, the base station antennas 5a and 7a). For example, the communication quality may be the probability of arrival (that is, the ratio of the number of packets received by the mobile station antenna 1a to the number of packets transmitted from the target base station). In this case, the number of packets transmitted from the base station is known and may be stored in the quality measurement unit 11. The quality measurement unit 11 separately measures the intensities of a plurality of radio waves transmitted from the plurality of base stations 5 and 7, respectively, and received by the mobile station antenna 1a. When the set frequency is different for each of the base stations 5 and 7 as described above, the quality measurement unit 11 starts from the plurality of base station antennas 5a and 7a based on the set frequencies of the base stations 5 and 7, respectively. The intensities of a plurality of radio waves transmitted and received by the mobile station antenna 1a are measured separately from each other. In order to make such measurement of radio wave strength repeatable, each base station 5 or 7 transmits radio waves of the set frequencies of the base stations 5 and 7 from the base station antennas 5a and 7a at the same timing, for example. You may repeat.

The parameter measuring device 13 measures the values of one or a plurality of parameters whose values fluctuate according to changes in the communication environment between the mobile station 1 and the base stations 5 and 7 and affect the communication quality. The one or more parameters are hereinafter simply referred to as measurement parameters. The measurement parameter includes at least one or a plurality (that is, one, two, three or all) of the first to fourth parameters described below.

The first parameter is a parameter representing the geometrical relationship between the base station antennas 5a and 7a and the mobile station antenna 1a.
The second parameter is a parameter representing the geometrical relationship between the base station antennas 5a and 7a, the mobile station antenna 1a, and the radio wave obstacle 2.
The third parameter is a parameter representing the orientation of the base station antennas 5a and 7a as seen from the mobile station antenna 1a.
The fourth parameter is a parameter representing the position of the mobile station antenna 1a.

The measurement parameters include at least one of the first to fourth parameters (ie, one, two, three or all). That is, the measurement parameter may be one, two, three, or all possible options selected from the first to fourth parameters. The measurement parameter may include at least one or a plurality (for example, all) of the first to third parameters, and may not include the fourth parameter.

3 and 4 are diagrams for explaining the parameters, and are plan views corresponding to FIG. 1. Hereinafter, specific examples of the first to fourth parameters will be described.

<First parameter>
The first parameter may be a parameter D _n indicating the length of a three-dimensional line segment connecting the base station antennas 5a and 7a and the mobile station antenna 1a. The first parameter D _n is measured by the parameter measuring device 13 for each of the base stations 5 and 7. Here, the subscript _n of D _n is an identification number of base stations 5 and 7. In FIG. 3, for example, the first parameter D _{1 for one} base station 5 is the length of the line segment connecting the base station antenna 5a and the mobile station antenna 1a, and the first parameter D ₁ for the other base station 7. Parameter D _{2 of} is the length of the line segment connecting the base station antenna 7a and the mobile station antenna 1a.

In order to measure the first parameter D _n , the parameter measuring device 13 sets the position measuring device 13a for measuring the position of the mobile station antenna 1a and the known positions (three-dimensional positions) of the base station antennas 5a and 7a. It has a stored antenna storage unit 13b and a calculation unit 13c.

The position measuring instrument 13a may use GNSS (Global Navigation Satellite System). That is, the position measuring instrument 13a receives positioning signals from a plurality of artificial satellites, and is required based on the transmission time of the signal included in each positioning signal, the position information of the artificial satellite, and the reception time of each positioning signal. Further, the position of the mobile station antenna 1a is calculated based on the known positional relationship between the position measuring instrument 13a and the mobile station antenna 1a in the mobile device 20. Instead, the position measuring instrument 13a measures the moving speed (vector representing the speed and the moving direction) of the moving device 20, and based on the measured speed and the known initial position of the moving device 20, the mobile station antenna 1a The position may be calculated. Alternatively, the position measuring instrument 13a may calculate the position of the mobile station antenna 1a by using both the method using the positioning signal and the method using the moving speed of the mobile device 20. Based on the position of the mobile station antenna 1a measured by the position measuring instrument 13a and the positions of the base station antennas 5a and 7a stored in the antenna storage unit 13b, the calculation unit 13c is used for each of the base stations 5 and 7. The parameter D _n of 1 is calculated.

<Second parameter>
The second parameter may include one or both of parameter L _n and parameter H _n . The parameter L _n indicates the length of the shortest path avoiding the radio wave obstacle 2 among the three-dimensional paths from the base station antennas 5a and 7a to the mobile station antenna 1a.

Here, the radio wave obstacle 2 may be a radio wave obstacle existing outside the mobile device 20. Further, the parameter L _n is measured for each base stations 5 and 7. Here, the subscript _n of L _n is an identification number of base stations 5 and 7. In FIG. 3, the parameter L1 for _one base station 5 connects the length of a three-dimensional line segment connecting the base station antenna 5a and the corner Pa of the radio interference obstacle 2 and the corner Pa and the mobile station antenna 1a. It is the sum of the length of the three-dimensional line segment. Here, the angle Pa means a vertical position through which the shortest path passes at the angle Pa in FIG. In FIG. 3, the parameter L ₂ for the other base station 7 is a line connecting the base station antenna 7a and the mobile station antenna 1a because there is no radio interference 2 between the base station antenna 7a and the radio wave obstacle 2. The length of the minute. Therefore, in FIG. 3, L ₂ is equal to D ₂ .

In order to measure the parameter L _n , the parameter measuring device 13 further includes a radio wave obstacle storage unit 13d that stores known radio wave obstacle data. The radio wave obstacle data represents the range occupied in space by the radio wave obstacle 2 that may exist between the base station antennas 5a and 7a and the mobile station antenna 1a (that is, the position, shape, and dimensions of the radio wave obstacle 2). .. The calculation unit 13c includes the position of the mobile station antenna 1a measured by the position measuring instrument 13a, the positions of the base station antennas 5a and 7a stored in the antenna storage unit 13b, and the radio wave stored in the radio wave obstacle storage unit 13d. based on the obstacle data, calculates the parameters L _n for each base station 5 and 7.

The parameters H _n are the base station antennas 5a and 7a and the mobile station antenna 1a from each point on the three-dimensional shortest path of the base station antennas 5a and 7a and the mobile station antenna 1a avoiding the radio wave obstacle 2. It shows the maximum length of the vertical lines drawn down to the three-dimensional line connecting with.

Further, the parameter H _n is measured for each base stations 5 and 7. Here, the subscript _n of H _n is an identification number of base stations 5 and 7. In FIG. 3, the parameter H ₁ for one base station 5 is the length of a perpendicular line drawn from the angle Pa to the line segment connecting the base station antenna 5a and the mobile station antenna 1a. That is, the parameter H ₁ is the length from the angle Pa to the foot Pb of the perpendicular line. In FIG. 3, the value of the parameter H ₂ for the other base station 7 is zero.

The calculation unit 13c includes the position of the mobile station antenna 1a measured by the position measuring instrument 13a, the positions of the base station antennas 5a and 7a stored in the antenna storage unit 13b, and the radio wave stored in the radio wave obstacle storage unit 13d. The parameter H _n is calculated for each of the base stations 5 and 7 based on the obstacle data.

<Third parameter>
The third parameter may be a parameter θ _n representing the orientation of the base station antennas 5a and 7a as seen from the mobile station antenna 1a. FIG. 4 is a diagram for explaining the third parameter, and is a plan view corresponding to FIG. The third parameter θ _n is measured for each base stations 5 and 7. Here, the subscript _n of θ _n is an identification number of base stations 5 and 7.

The third parameter theta _n, for example, as shown in FIG. 4, the reference point Pc and the base station antenna 5a on the mobile station antenna 1a, a vertical surface S _n including the reference point Pd on 7a, the mobile station antenna 1a it may be the angle between the reference vertical plane S _r including the reference point Pc of the above. Subscript n in the vertical plane S _n is an identification number indicating whether the vertical plane about which base station 5,7. Reference vertical plane S _r is a vertical line including the reference point Pc is a vertical plane and horizontal end is fixed to the mobile device 20.

In one example, when the vertical surface S _n is present on the left side of the reference vertical plane S _r as viewed from the mobile station antenna 1a, the parameter theta _n takes a positive value, the reference vertical plane as viewed from the mobile station antenna 1a when than S _r to the presence of the vertical plane S _n on the right, the parameter theta _n may take a negative value. In this case, the parameter θ _n takes a value from −180 degrees to +180 degrees.

In FIG. 4, for one base station 5, the parameter θ ₁ is the angle formed by the vertical plane S ₁ and the reference vertical plane S _r , and for the other base station 7, the parameter θ ₂ is the vertical plane S ₂ . This is the angle formed by the reference vertical plane _Sr.

In order to measure the parameter θ _n , the parameter measuring device 13 includes a direction sensor 13e that measures the direction of the moving device 20. Here, the orientation of the moving device 20 may be, for example, the orientation in the coordinate system fixed to the road surface on which the moving device 20 moves in the area A (for example, the orientation of the coordinate system with respect to the horizontal coordinate axis). This orientation may be around the vertical axis. The orientation sensor 13e, for example, obtains the orientation of the moving device 20 by integrating the measured angular velocity with a gyro sensor that measures the angular velocity of the moving device 20 around the yaw axis (vertical axis) of the moving device 20. It may have a calculation unit. In this case, it is assumed that the initial value of the orientation (angle) of the moving device 20 is known.

The calculation unit 13c is the position of the mobile station antenna 1a measured by the position measuring instrument 13a, the positions of the base station antennas 5a and 7a stored in the antenna storage unit 13b, and the orientation of the moving device 20 measured by the orientation sensor 13e. Based on the above, the parameter θ _n is calculated for each of the base stations 5 and 7.

When the position and orientation of the mobile device 20 are within a specific range, the mobile station antenna 1a and the base station antenna are placed on a three-dimensional line segment connecting the mobile station antenna 1a and the base station antennas 5a and 7a. The third parameter is effective when the load (for example, the container 19 described later) or the structure on the moving device 20 is positioned so as to block the 5a and 7a from each other. In this case, the value of the third parameter θ _n indicates whether or not the load or structure on the moving device 20 is located on the three-dimensional line segment.

<Fourth parameter>
The fourth parameter may be a parameter representing the position of the mobile station antenna 1a. Here, the position of the mobile station antenna 1a may be represented as a position in a coordinate system having an x-axis, a y-axis, and a z-axis orthogonal to each other. This coordinate system may be a coordinate system for representing the position in the area A described above. The fourth parameter may include a parameter that is a value of the x-axis coordinate, a parameter that is a value of the y-axis coordinate, and a parameter that is a value of the z-axis coordinate in such a coordinate system. Each such parameter may be measured by the position measuring instrument 13a.

When the moving device 20 moves on the horizontal plane in the area A and does not move in the vertical direction, the parameter indicating the vertical position of the mobile station antenna 1a may not exist as the fourth parameter. For example, when the above-mentioned x-axis and y-axis are coordinate axes facing in the horizontal direction, there are a parameter that is the value of the x-axis coordinate and a parameter that is the value of the y-axis coordinate as the fourth parameter. The parameter that is the value of the z-axis coordinates does not have to exist.

<Fifth parameter>
The above-mentioned measurement parameters may include a fifth parameter in addition to at least one of the above-mentioned first to fourth parameters. The fifth parameter is a parameter V _n indicating the speed of the mobile station antenna 1a with respect to the base station antennas 5a and 7a. V _n is measured for each base station. Here, V _{n for} each base station antenna 5a, 7a is a positive value when the mobile station antenna 1a is close to the base station antennas 5a, 7a, and the mobile station antenna 1a is the base station antenna. When it is far from 5a and 7a, it is a negative value.

In one example, the parameter V _n has the same absolute value as the measured moving speed Va of the mobile device 20, and when the mobile device 20 is approaching the base station antennas 5a, 7a, the sign of V _n . Is positive, and when the mobile device 20 is away from the base station antennas 5a and 7a, the sign of V _n is negative.

In order to measure the speed parameter V _n , the parameter measuring device 13 includes a speed sensor 13f for measuring the speed of the moving device 20. Here, when the moving device 20 is a vehicle, for example, the speed sensor 13f measures the rotation speed of the wheels of the vehicle, and obtains the moving speed Va of the moving device 20 based on the measured rotation speed. .. Further, in the calculation unit 13c, the position of the mobile station antenna 1a measured by the position measuring instrument 13a, the positions of the base station antennas 5a and 7a stored in the antenna storage unit 13b, and the orientation sensor 13e described above are used. The code of the parameter V _n measured by the speed sensor 13f is determined based on the measured orientation of the moving device 20 and the code of the moving speed Va (whether the moving device 20 is moving forward or backward).

In another example, the velocity parameter V _n may be the velocity of the mobile station antenna 1a with respect to the base station antennas 5a, 7a. That is, when the vector representing the moving speed of the moving device 20 is V, the component of V in the direction from the mobile station antenna 1a to the base station antennas 5a and 7a may be V _n . In this case, when the mobile device 20 is approaching the base station antennas 5a, 7a, the value of V _n becomes positive, and when the mobile device 20 is away from the base station antennas 5a, 7a, the value of V _n The value will be negative. Further, in this case, the calculation unit 13c has the position of the mobile station antenna 1a measured by the position measuring instrument 13a, the position of the base station antennas 5a and 7a stored in the antenna storage unit 13b, and the above-mentioned orientation. The parameter V _n may be obtained based on the orientation of the moving device 20 measured by the sensor 13e and the moving speed Va of the moving device 20 measured by the speed sensor 13f.

The machine learning device 15 machine-learns the relationship between the value of the measurement parameter and the base stations 5 and 7 to be selected based on the measurement results of the quality measurement unit 11 and the parameter measurement device 13. The machine learning device 15 has an input processing unit 15a, a storage unit 15b, and a learning unit 15c.

The measurement results by the quality measurement unit 11 and the parameter measurement device 13 are input to the input processing unit 15a. The input processing unit 15a generates training data based on the measurement result each time the measurement result is input. Of the communication qualities of the base stations 5 and 7 measured simultaneously by the quality measurement unit 11, the base station 5 or 7 having the maximum communication quality is selected as the base station to be selected (hereinafter, also simply referred to as the selected base station). The training data includes information indicating the selected base station and the values of measurement parameters (each parameter) measured by the parameter measuring device 13 when measuring the communication quality of the selected base station. The input processing unit 15a stores each generated training data in the storage unit 15b.

The learning unit 15c machine-learns the relationship between the value of the measurement parameter and the selected base station based on a large number of acquired training data. In the present embodiment, the learning unit 15c machine-learns the relationship between the value of the measurement parameter and the selected base station by using a support vector machine (hereinafter referred to as SVM (Support Vector Machine)) used for data classification. The learning unit 15c may machine-learn the relationship between the value of the measurement parameter and the selected base station by another method (for example, deep learning).

<When the number of parameters is two>
In order to make the explanation of machine learning by SVM easy to understand, a case where two parameters α and β exist as measurement parameters and two base stations 5 and 7 exist as shown in FIG. 1 will be described. FIG. 5A shows a two-dimensional coordinate system representing a large number of acquired training data. In FIG. 5A, the horizontal axis represents the value of one parameter α, and the vertical axis represents the value of the other parameter β. In FIG. 5A, each black circle indicates training data in which the selected base station is one base station 5 (hereinafter referred to as first data), and each white circle indicates that the selected base station is the other base station 7. The training data (hereinafter referred to as the second data) is shown.

In the two-dimensional coordinate system as shown in FIG. 5A, the learning unit 15c has a margin M, which will be described later, among various discriminant functions F representing boundaries that separate a set of first data and a set of second data from each other. Find the maximum discriminant function F _max . Each discriminant function F is a function (that is, β = F (α)) that determines the value of the parameter β with respect to each value of the parameter α. Further, in each discriminant function F, the distance from the boundary represented by the discriminant function F to the first data (black circle in FIG. 5A) closest to the boundary is the second data (the second data closest to the boundary from the boundary). It is set to be the same as the distance to (white circle) in FIG. 5 (A). Further, each of the distances is the margin M. The discriminant function F represents a one-dimensional boundary when the number of measurement parameters is two, as shown in FIG. 5 (A). The discriminant function F may be a linear function as shown in FIG. 5A, or may be another kind of function.

In FIG. 5A, the discriminant function F _{max at} which the margin M is maximized is shown. FIG. 5B shows an identification function Fi in which the margin M is not maximized. That is, in FIG. 5 (B), the shows discriminant function F _i for collection of collection and the second data having the same first data as in FIG. 5 (A). Margin M when the discriminant function _{F i} in FIG. 5 (B), less than the margin M in FIG. 5 (A).

In the coordinate space of FIG. 5A, the two regions divided by the boundary represented by the identification function F _max are the first region R1 in which one base station 5 is the selected base station and the other base station 7, respectively. Is the second region R2 serving as the selected base station. Learning unit 15c, such discriminant function F _max, and machine learning as the relationship between the selected base station to the value of the measured parameter, and stores the identification function F _max in the storage unit 15b.

The learning unit 15c may obtain a new discriminant function F _max each time new training data is stored in the storage unit 15b. Alternatively, when the number of training data newly stored in the storage unit 15b reaches a predetermined number from the time when the discriminant function F _max was obtained last time, the learning unit 15c registers the training data stored in the storage unit 15b. Based on this, a new discriminant function F _max may be obtained.

<When the number of parameters is 3 or more>
When the number of measurement parameters included in the training data is n (n is an integer of 3 or more), the learning unit 15c has a discriminant function F in an n-dimensional coordinate system having n coordinate axes indicating parameters different from each other. _{Find max} . This discriminant function F _max represents a boundary of the (n-1) dimension. This boundary divides the n-dimensional coordinate space into the first region R1 and the second region R2 as described above. Such identification function F _max, when applied among the n parameter values (n-1) number of parameters to identify the function F _max, determined the values of the remaining parameters. For example, when the parameter consists of the above-mentioned D ₁ , D ₂ , L ₁ , L ₂ , H ₁ , H ₂ , θ ₁ , θ ₂ , V ₁ , and V ₂ , n = 10. The identification function F _max is obtained in the 10-dimensional coordinate system.

The selection unit 17 selects the base station 5 or 7 with which the mobile station 1 communicates based on the machine-learned relationship (identification function F _max ) and the value of each parameter measured by the parameter measuring device 13. .. In the present embodiment, the selection unit 17 selects the base station 5 or 7 with which the mobile station 1 communicates, based on the combination of the measured values of the plurality of parameters and the identification function F _max which is the above-mentioned relationship. That is, the selection unit 17 determines which of the two regions (first region R1 and second region R2) separated by the boundary represented by the discrimination function F _max belongs to the combination of the measured values of the plurality of parameters. Then, the base station 5 or 7 corresponding to the area to which the combination belongs is selected as the base station with which the mobile station 1 communicates. For example, when the combination of the measured values of the plurality of parameters belongs to the first region R1, the selection unit 17 selects one base station 5 as the base station with which the mobile station 1 communicates. When the combination of the measured values of the plurality of parameters belongs to the second region R2, the selection unit 17 selects the other base station 7 as the base station with which the mobile station 1 communicates.

<When the number of base stations is 3 or more>
An example will be described when the number of base stations is m (m is an integer of 3 or more). The learning unit 15c obtains the above-mentioned discrimination function F _max for all the sets of the two base stations selected from the m base stations. The discriminant function F _max for each set assumes that there are only two base stations that make up the set, a collection of training data in which the selected base station is one base station, and a collection of training data in which the selected base station is the other base. It represents the boundary that separates a collection of training data, which is a station, from each other. The other points of the identification function F _max are the same as described above.

The selection unit 17 selects the base station with which the mobile station 1 communicates based on the machine-learned identification function F _max for each set and the value of each parameter measured by the parameter measuring device 13. That is, for each set, the selection unit 17 provisionally selects the base station with which the mobile station 1 communicates, based on the combination of the measured values of the plurality of parameters and the identification function F _{max of the} set. As a result, the most selected base station is finally selected as the base station with which the mobile station 1 communicates.

(Base station selection method)
FIG. 6 is a flowchart showing a base station selection method according to the embodiment of the present invention. This method is performed using the base station selection device 10 described above. The base station selection method includes machine learning processing and selection processing. The machine learning process includes steps S1 and S2, and the selection process includes steps S3 and S4.

In step S1, the quality measuring unit 11 measures the communication quality between the mobile station antenna 1a and the base station for each of the base stations 5 and 7, and at the same time, the parameter measuring device 13 measures the value of the measurement parameter.

In step S2, the machine learning device 15 obtains the relationship between the value of the measurement parameter and the selected base station (identification function F _max ) based on the measurement result in step S1.

In one example, if a large number of measurement results are obtained by repeating step S1, in step S2, based on the large number of measurement results (for example, based on a large number of the above training data based on the large number of measurement results). ), The machine learning device 15 obtains the relationship (identification function F _max ) between the value of the measurement parameter and the selected base station.

In another example, steps S1 and S2 are repeated. In the second and subsequent steps S2, the machine learning device 15 is based on the measurement results in each step S1 already performed (for example, based on a large number of the training data based on the large number of measurement results). Discrimination function F _max ) is obtained.

In order to repeat step S1 or steps S1 and S2, radio waves whose strength is measured by the quality measuring unit 11 in step S1 are repeatedly transmitted (for example, at a predetermined cycle) from the plurality of base stations 5 and 7. Will be done.

In step S3, the parameter measuring device 13 measures the value of the measurement parameter. The combination of parameters measured in step S3 is the same as the combination of parameters measured in step S1.

In step S4, the selection unit 17 is a base station with which the mobile station 1 communicates, based on the value of the measurement parameter measured in step S3 and the latest relationship (identification function F _max ) obtained in step S2. Select 5 or 7.

In step S5, it is determined whether the base station 5 or 7 with which the mobile station 1 is currently communicating is different from the base station selected in step S4. If the result of this determination is affirmative, the process proceeds to step S6, and if not, the process proceeds to step S7.

In step S6, the selection unit 17 switches the base station with which the mobile station 1 communicates from the base station 5 or 7 currently communicating with the base station selected in step S4. For example, a frequency for communication is set in each of the base stations 5 and 7, and when this frequency (set frequency) is different for each base station, the mobile station 1 communicates with the selection unit 17. The frequency of the radio wave to be used is switched to the set frequency of the base station 5 or 7 selected in step S4. As a result, for example, in the mobile station 1, the signal input unit 1b extracts a command signal of a radio wave having the same frequency as the set frequency of the base station selected in step S4 from the radio waves received by the mobile station antenna 1a. The extracted command signal is output to the control unit 9.
On the other hand, in step S7, the mobile station 1 continues communication with the base station 5 or 7 currently communicating.

Such selection processes S3 to S7 are repeatedly performed while the moving device 20 is moving. In this case, step S8 may be performed when step S3 is performed. In step S8, the quality measurement unit 11 measures the communication quality between the mobile station antenna 1a and the base station for each of the base stations 5 and 7. Based on the measurement results of the measurement parameter values measured in step S3 and the communication quality of each of the base stations 5 and 7 measured in step S8, the machine learning device 15 described above. Step S2 is performed. In this step S2, the machine learning device 15 sets the value of the measurement parameter and the selected base station based on the large number of measurement results already obtained and the measurement results obtained in steps S3 and S8 this time. _{Find the} relationship (discrimination function F _max ).

[Example]
A case where the base station selection device 10 is applied to the mobile device 20 traveling in a predetermined area A of the container terminal will be described. FIG. 7 is a plan view showing an outline of the container terminal. In FIG. 7, the alternate long and short dash line indicates the path through which the moving device 20 moves.

The moving device 20 transports the container 19 to the container storage areas B1, B2 and B3, or receives the container 19 from the container storage areas B1, B2 and B3 and transports the container 19 to another position (for example, the position P1 in FIG. 7). The state of the container storage areas B1, B2, and B3 depends on the number of containers 19 loaded in each area of the container storage areas B1, B2, and B3 (that is, how many containers 19 are loaded in which area). It changes to one of the possible multiple (for example, many) container placement states. The container placement state represents the number of containers 19 loaded in each area of the container storage areas B1, B2, and B3. In the example of FIG. 7, there are three blocks B1, B2, and B3 shown by broken lines as container storage areas. Each block B1, B2, B3 has a large number of container loading areas as defined by broken lines, and a plurality of containers 19 are stacked in a plurality of stages in the vertical direction in each container loading area. ing.

FIG. 8 is a side view of an automatic transport vehicle which is an example of the moving device 20 in FIG. 7. In FIG. 8, the automatic transport vehicle is, for example, a vehicle having a towing vehicle 20a and a trailer 20b towed by the towing vehicle 20a. In FIG. 8, a container 19 that acts as an electromagnetic interference is placed on the trailer 20b. According to the value of the third parameter θ _n described above, on the three-dimensional line segment connecting the mobile station antenna 1a and the base station antennas 5a and 7a of the base stations 5 and 7, the load on the mobile device 20 A container 19 may or may not be located. In the example of FIG. 8, the upper end of the mobile station antenna 1a is lower than the upper end of the container 19 placed on the trailer 20b.

In the example of FIG. 7, the moving device 20 performs a container transport operation. That is, the moving device 20 moves between the position of the container ship 21 and the container storage areas B1, B2, B3, and transports the container 19 from the container ship 21 to the container storage areas B1, B2, B3, or the container storage area. The containers 19 of B1, B2 and B3 are transported to the container ship 21. A gripping device (crane) 23 is provided for the container ship 21. The gripping device 23 grips and places the container 19 of the container ship 21 on the moving device 20 that has moved to the position P1 of the gripping device 23. Alternatively, the gripping device 23 grips the container 19 on the moving device 20 that has moved to the position P1 of the gripping device 23 and places it on the container ship 21.

Each block B1, B2, B3, which is a container storage place, is provided with a gripping device (crane) 25 that grips the container 19 and places it in the container loading area of any of the blocks B1, B2, B3. When the moving device 20 conveys the container 19 to the container yard B1, B2, B3, the moving device 20 is the position of the gripping device 25 in the container yard B1, B2, B3 (for example, the block B1, B2 or B3 in FIG. Moving to position P2), with the moving device 20 in that position, the gripping device 25 grips the container 19 on the moving device 20 and either of the container loading areas in the corresponding blocks B1, B2 or B3. Put in. When the moving device 20 conveys the container 19 from the container storage areas B1, B2 and B3, the moving device 20 moves to the position of the gripping device 25 in any of the container storage areas B1, B2 or B3 (for example, the position P2 in FIG. With the moving device 20 in the position, the gripping device 25 grips the container 19 in any of the container loading areas in the blocks B1, B2 or B3 and is placed on the moving device 20 (for example, on the trailer 20b). Put in. Each gripping device 25 can be moved in the vertical direction of FIG. 7 by a driving device provided in the gripping device 25.

The command device 3 performs container transport control for transporting a large number of containers 19 from the container ship 21 to the container storage areas B1, B2, B3 or from the container storage areas B1, B2, B3 to the container ship 21. That is, the command device 3 is such that the container 19 is transported from the container ship 21 to the container yard B1, B2, B3 or from the container yard B1, B2, B3 to the container ship 21 according to, for example, a predetermined container transport plan. , Controls the moving device 20 and the gripping devices 23 and 25, respectively. The container transport plan defines the order of blocks B1, B2, B3 to which the container 19 is carried out and the container loading area thereof, or blocks B1, B2, B3 to which the container 19 is carried and the container loading area thereof. The order of is defined. In the container transport control, the command signal from the command device 3 is transmitted from the base stations 5 and 7 to the mobile station 1 by radio waves. As a result, the mobile device 20 performs the container transport operation according to the command signal received from the base station 5 or 7 selected by the selection unit 17. Further, the command device 3 controls the operation of the gripping devices 23 and 25 in the container transfer control.

Further, in the container transport control, the command device 3 grasps the change in the container loading state of the container storage areas B1, B2, and B3 based on the container transport plan, and each time the container loading state changes, the latest container. Information indicating the mounting state (hereinafter referred to as container mounting information) is transmitted to the mobile station 1 via the base stations 5 and 7. Alternatively, each container loading area is provided with a sensor that detects the number of containers 19 stacked in the area, and based on the detection results of these sensors, the command device 3 sets the container storage areas B1 and B2. , B3 grasps the change in the container mounting state, and each time the container mounting state changes, the latest container mounting information is transmitted to the mobile station 1 via the base stations 5 and 7. As a result, the mobile station 1 receives the latest container placement information received from the base station 5 or 7 selected by the selection unit 17. The selection unit 17 receives and stores the latest container placement information from the mobile station 1.

The machine learning device 15 machine-learns the above relationship (discrimination function F _max ) by repeatedly performing the above-mentioned machine learning process for each container-mounted state. The above machine-learned relationship is stored in the storage unit 15b for each container placement state. This machine learning process may be performed while operating the gripping devices 23 and 25 and the moving device 20 by, for example, the command device 3 performing the container transfer control described above.

After that, the above-mentioned selection process is performed. That is, when the mobile device 20 is performing the container transfer work, the selection unit 17 determines the above relationship with the container placement information and the value of the measurement parameter based on the latest container placement information received from the mobile station 1. Based on the above, the base station 5 or 7 with which the mobile station antenna 1a communicates is selected. When the mobile device 20 is performing the container transport work, the above-mentioned machine learning process may be repeatedly performed on the latest container placement information received by the mobile station 1.

Further, since the container 19 in the container storage areas B1, B2, and B3 becomes an electromagnetic interference obstacle 2 (FIG. 1), the parameter measuring device 13 is the latest container received by the mobile station 1 in the above-mentioned machine learning process and selection process. Based on the placement information, the radio interference data stored in the radio interference storage unit 13d is updated, and the second parameters L _n and H _n are obtained using the updated latest radio interference data.

According to the above-described embodiment, the communication quality between the base stations 5 and 7 and the mobile station 1 is measured, and the value fluctuates according to the change in the communication environment between the mobile station 1 and the base stations 5 and 7. The parameters are measured, and based on the measurement results, the relationship between the values of the measurement parameters and the selected base station is machine-learned. In this way, the base station 5 or 7 is selected based on the above relationship machine-learned based on the parameter whose value fluctuates according to the change in the communication environment and the measured value of the parameter. Therefore, it is possible to select a base station in consideration of changes in the communication environment.

The present invention is not limited to the above-described embodiment, and it goes without saying that various modifications can be made within the scope of the technical idea of the present invention. For example, the base station selection device 10 according to the embodiment of the present invention may not have all of the above-mentioned plurality of items, or may have only a part of the above-mentioned plurality of items.

1 mobile station, 1a mobile station antenna, 1b signal input unit, 2 radio obstacles, 3 command device, 5 base station, 5a base station antenna, 5b transmission circuit, 7 base station, 7a base station antenna, 7b transmission circuit, 9 Control unit, 10 base station selection device, 11 quality measurement unit, 13 parameter measurement device, 13a position measurement device, 13b antenna storage unit, 13c calculation unit, 13d radio wave obstacle storage unit, 13e orientation sensor, 13f speed sensor, 15 machine Learning device, 15a input processing unit, 15b storage unit, 15c learning unit, 17 selection unit, 19 container, 20 moving device, 20a tow truck, 20b trailer, 21 container ship, 23 gripping device (crane), 25 gripping device (crane) ), 100 Communication system, Area A, B1, B2, B3 Container storage (block), P1 Container ship position, P2 Container storage position

Claims (8)

A base station selection device that selects a base station with which a mobile station communicates from a plurality of base stations.
For each base station, a quality measurement unit that measures the communication quality between the mobile station and the base station,
A parameter measuring device that measures the values of one or more parameters whose values fluctuate according to changes in the communication environment between the mobile station and the base station.
A machine learning device that machine-learns the relationship between the values of one or more parameters and a base station to be selected based on the measurement results of the quality measurement unit and the parameter measurement device.
A base station including the machine-learned relationship and a selection unit that selects the base station with which the mobile station communicates based on the values of the one or more parameters measured at the time of selecting the base station. Selection device. The mobile station has a mobile station antenna that receives radio waves from each of the base stations, and each base station has a base station antenna that transmits radio waves.
The one or more parameters
A first parameter representing the geometric relationship between the base station antenna and the mobile station antenna,
A second parameter representing the geometrical relationship between the base station antenna, the mobile station antenna, and radio interference.
Of the third parameter representing the orientation of the base station antenna as seen from the mobile station antenna and the fourth parameter representing the position of the mobile station antenna.
The base station selection device according to claim 1, which comprises at least one of them. The one or more parameters include the first parameter.
The first parameter is measured by the parameter measuring device for each base station, and indicates the length of a line segment connecting the base station antenna of the base station and the mobile station antenna, according to claim 2. Base station selection device. The one or more parameters include the second parameter.
As the second parameter,
A parameter that is measured for each base station and indicates the shortest distance between the base station antenna and the mobile station antenna of the base station while avoiding radio interference, and
The base station antenna and the mobile station antenna are connected from each point on the shortest path of the base station antenna and the mobile station antenna, which is measured for each base station and avoids radio obstacles. The base station selection device according to claim 2 or 3, wherein one or both of the parameters indicating the maximum length of the vertical lines drawn down to the line segment are used. The one or more parameters include the third parameter.
The mobile station antenna is provided in the mobile device.
Any of claims 2 to 4, wherein the load or structure on the mobile device is located on the line segment connecting the mobile station antenna and the base station antenna according to the value of the third parameter. The base station selection device according to item 1. The one or more parameters include a fifth parameter indicating the speed of the mobile station antenna for each base station antenna.
The velocity with respect to each of the base station antennas is a positive value when the mobile station antenna is approaching the base station antenna, and is a positive value when the mobile station antenna is moving away from the base station antenna. The base station selection device according to any one of claims 2 to 5, which is a negative value. The mobile station is provided in a mobile device that transports a container to a container yard or a container in a container yard to another position.
The state of the container yard changes to one of a plurality of possible container yard states depending on the number of containers loaded in each area of the container yard.
The machine learning device machine-learns the relationship between the values of the one or more parameters and the base station to be selected for each of the container-mounted states.
The selection unit receives information indicating the latest container mounting state, and based on the relationship with the latest container mounting state and the measured values of the one or more parameters, the mobile station. The base station selection device according to any one of claims 1 to 6, wherein the base station with which the user communicates is selected. This is a base station selection method for selecting a base station with which a mobile station communicates from a plurality of base stations.
(A) For each base station, the communication quality between the mobile station and the base station is measured.
(B) Measure the values of one or more parameters whose values fluctuate according to changes in the communication environment between the mobile station and the base station.
(C) Based on the measurement results of the above (A) and the above (B), the relationship between the values of the one or more parameters and the base station to be selected is machine-learned.
(D) A base station selection method for selecting the base station with which the mobile station communicates based on the machine-learned relationship and the value of the one or more parameters measured at the time of selecting the base station.

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