JP2021149565A - Moving object detection system - Google Patents

Abstract

To provide a moving object detection system with high detecting precision of a moving object.SOLUTION: A moving object detection system comprises a plurality of first server groups and a second server. The first server group comprises a first server and a plurality of sensor units capable of communicating with the first server. The second server predicts a future route of the moving object and transmits second server information including an arrival position where the moving object reaches a detectable range of the moving object in any of the first server groups to the first server. The first server enhances a temporal or spatial resolution of the sensor in a range including the arrival position.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a mobile detection system.

Patent Document 1 discloses a mobile detection system. The moving object detection system uses a plurality of sensors to detect a moving object.

US10084961 B2 Gazette

It is required to further improve the detection accuracy of moving objects. In one aspect of the present disclosure, it is preferable to provide a moving object detection system having high moving object detection accuracy.

One aspect of the present disclosure includes a plurality of first server groups and a second server, wherein the first server group includes a first server, a plurality of sensor units capable of communicating with the first server, and the like. It is a moving body detection system including.

The sensor unit is arranged on the road or at a position facing the road. The sensor unit is configured to detect the position of the moving body and generate sensor information indicating the position of the moving body, and a sensor configured to transmit the sensor information to the first server. It is equipped with an information transmission unit.

The first server is based on a first server receiving unit configured to receive a plurality of the sensor information from the plurality of sensor units and a plurality of the sensor information received by the first server receiving unit. A position estimation unit configured to estimate the position of the moving body and a first server information representing the position of the moving body estimated by the position estimation unit are transmitted to the second server. It includes a server information transmission unit.

The second server moves based on the second server receiving unit configured to receive the first server information from the first server and the first server information received by the second server receiving unit. Based on a route estimation unit configured to predict the future route of the body and the future route of the moving body estimated by the route estimating unit, the moving body moves in any of the first server groups. The arrival position estimation unit configured to estimate the arrival position to reach the detectable range of the body, and the second server information including the arrival position, correspond to the arrival position estimated by the arrival position estimation unit. It includes a second server information transmission unit configured to transmit to the first server included in the first server group.

The first server receiving unit is configured to receive the second server information. When the first server receives the second server information, the first server increases the temporal or spatial resolution of the sensor in the range including the arrival position as compared with the case where the second server information is not received. A sensor instruction unit for instructing the sensor unit is provided.

The moving object detection system, which is one aspect of the present disclosure, can improve the detection accuracy of the moving object.
Another aspect of the present disclosure is a mobile detection system comprising a plurality of sensor units and a server capable of communicating with the sensor units.

The sensor unit creates sensor information representing the position of the moving body based on a sensor configured to detect the position of the moving body and the detection result of the sensor, and transmits the sensor information to the server. A sensor information transmission unit configured as described above is provided.

The server weights and weights each of the server receiving unit configured to receive the plurality of the sensor information from the plurality of the sensor units and the plurality of the sensor information received by the server receiving unit. It includes a position estimation unit configured to estimate the position of the moving body based on the plurality of sensor information.

The server or the sensor unit is a weighting setting unit configured to set the weighting of the sensor information smaller as the position of the moving body represented by the sensor information is closer to the boundary of the detection range of the sensor. Be prepared.

The position estimation unit is configured to estimate the position of the moving body by using the weighting set by the weighting setting unit.
The mobile detection system, which is another aspect of the present disclosure, can improve the detection accuracy of the moving body.

Another aspect of the present disclosure is a mobile detection system comprising a plurality of sensor units and a server capable of communicating with the sensor units.
The sensor unit creates sensor information representing the existence probability of the moving body for each of a plurality of grids based on a sensor configured to detect the position of the moving body and the detection result of the sensor, and the sensor. It includes a sensor information transmission unit configured to transmit information to the server.

The server includes a server receiving unit configured to receive a plurality of the sensor information from the plurality of sensor units, a grid setting unit configured to set the size of the grid in the sensor information, and the like. The position of the moving body is estimated by calculating the existence probability of the moving body for each of the plurality of the grids by using the plurality of sensor information having the size of the grid set by the grid setting unit. It comprises a position estimation unit configured to do so.

When the grid setting unit has a relatively high existence probability and a specific grid located near the boundary of the detection range of the sensor exists in the grid, the size of the grid in the range including the specific grid is large. Is set smaller than when the specific grid does not exist.

The mobile detection system, which is another aspect of the present disclosure, can improve the detection accuracy of the moving body.

It is a block diagram which shows the structure of the moving body detection system 1. It is a block diagram which shows the structure of the 1st server 7. It is a block diagram which shows the structure of a sensor unit 9. It is a sequence diagram which shows the process which a moving body detection system 1 executes. It is a block diagram which shows the structure of the moving body detection system 101. It is a sequence diagram which shows the process which a moving body detection system 101 executes. It is explanatory drawing which shows the sensor information. It is explanatory drawing which shows the sensor information when the specific grid 31C exists. It is explanatory drawing which shows the sensor information when the specific grid 31C does not exist.

An exemplary embodiment of the present disclosure will be described with reference to the drawings.
<First Embodiment>
1. 1. Configuration of Mobile Detection System 1 The configuration of the mobile detection system 1 will be described with reference to FIGS. 1 to 3. As shown in FIG. 1, the mobile detection system 1 includes a plurality of first server groups 3A and 3B, and a second server 5. The first server groups 3A and 3B have a similar configuration. Here, the first server group 3A will be described. In the present embodiment, the mobile detection system 1 includes two first server groups 3A and 3B, but the number of the first server groups is not particularly limited and may be 3 or more.

The first server group 3A includes a first server 7 and a plurality of sensor units 9. Each of the plurality of sensor units 9 can communicate with the first server 7. As shown in FIG. 2, the first server 7 includes a control unit 11 and a transmitter / receiver 13. The control unit 11 includes a macro computer. The transmitter / receiver 13 can transmit / receive information to / from the sensor unit 9.

The sensor unit 9 is arranged on the road or at a position facing the road. The sensor unit 9 is mounted on a vehicle, for example. As shown in FIG. 3, the sensor unit 9 includes a sensor 15, a control unit 17, and a transmitter / receiver 19.

The sensor 15 detects the moving body 21 shown in FIG. 1 and generates sensor information. Examples of the moving body 21 include a vehicle, a walking vehicle, a bicycle, and the like. The sensor information is information representing the position of the moving body 21. The sensor 15 is, for example, a camera, a rider, a millimeter wave radar, a sonar, or the like. The control unit 17 includes a microcomputer. The transmitter / receiver 19 can transmit / receive information to / from the first server 7.

The first server group 3A has a detectable range of 23A. The first server group 3B has a detectable range 23B. The detectable range 23A is a range in which the moving body 21 can be detected by the sensor 15 included in the first server group 3A. The detectable range 23B is a range in which the moving body 21 can be detected by the sensor 15 included in the first server group 3B.

The detectable range 23A and the detectable range 23B partially overlap, for example, as shown in FIG. The detectable range 23A and the detectable range 23B do not have to overlap.
2. Basic processing executed by the mobile detection system 1 The basic processing executed by the mobile detection system 1 will be described. The sensor 15 included in the sensor unit 9 executes a process of detecting the moving body 21. When the moving body 21 is detected, the sensor 15 generates sensor information. The sensor unit 9 transmits sensor information to the first server 7 by using the control unit 17 and the transmitter / receiver 19. The sensor unit 9 that transmits sensor information and the first server 7 that receives sensor information belong to the same first server group. The control unit 17 and the transmitter / receiver 19 correspond to the sensor information transmission unit.

The first server 7 receives the transmitted sensor information by using the control unit 11 and the transmitter / receiver 13. When a plurality of sensor information is transmitted from the plurality of sensor units 9, the first server 7 receives each of the plurality of sensor information. The control unit 11 and the transmitter / receiver 13 correspond to the first server receiving unit.

For example, the plurality of sensor information received by the first server 7 is information representing the position of the same mobile body 21, respectively. The first server 7 uses the control unit 11 to estimate the position of one mobile body 21 based on the received plurality of sensor information. As a method of estimating the position of the moving body 21, for example, a method of three-point surveying and the like can be mentioned. The control unit 11 corresponds to the position estimation unit.

3. 3. Sensor resolution change processing executed by the mobile detection system 1 The sensor resolution change processing executed by the mobile detection system 1 will be described with reference to FIG. 4 with reference to the example shown in FIG. In step 1 of FIG. 4, the first server 7 included in the first server group 3A transmits the first server information to the second server 5 by using the control unit 11 and the transmitter / receiver 13. The first server information is information representing the position of the mobile body 21 estimated by the first server 7.

The first server information may include other information in addition to the information indicating the position of the mobile body 21. As other information, for example, there is information indicating the speed, acceleration, traveling direction, etc. of the moving body 21. The control unit 11 and the transmitter / receiver 13 correspond to the first server information transmission unit.

In step 2, the second server 5 receives the first server information. The second server 5 corresponds to the second server receiving unit.
The processes of step 1 and step 2 are repeatedly executed. As a result, the second server 5 receives a plurality of first server information. The plurality of first server information represents the position of the moving body 21 at different times. Therefore, the plurality of first server information is information indicating an mode in which the position of the mobile body 21 changes in time series.

In step 3, the second server 5 predicts the future route 25 of the mobile body 21 based on the plurality of first server information. An example of the future route 25 is shown in FIG. The second server 5 also predicts when the mobile 21 will reach an arbitrary position on the future route 25. The content of this prediction will be referred to as a time prediction below. The second server 5 corresponds to the route estimation unit.

In step 4, the second server 5 predicts the arrival position 27 based on the estimated future route 25. An example of the arrival position 27 is shown in FIG. The arrival position 27 is a position where the moving body 21 reaches the detectable range in any of the first server groups other than the first server group 3A, assuming that the moving body 21 travels on the future route 25. In the example shown in FIG. 1, the arrival position 27 is a position that reaches the detectable range 23B in the first server group 3B. The arrival position 27 is on a boundary line that divides the inside and outside of the detectable range 23B.

Further, the second server 5 predicts the time when the moving body 21 reaches the arrival position 27 (hereinafter referred to as the arrival prediction time) based on the future route 25 and the time prediction. The second server 5 corresponds to the arrival position estimation unit.

In step 5, the second server 5 transmits the second server information to the first server 7 included in the first server group 3B. The second server information is information including the arrival position 27 estimated in step 4 and the estimated arrival time. The second server 5 corresponds to the second server information transmission unit.

The first server group 3B is the first server group corresponding to the arrival position 27 in the example shown in FIG. The corresponding first server group corresponding to the arrival position 27 is a first server group in which the arrival position 27 exists in the detectable range.

In step 6, the first server 7 included in the first server group 3B receives the second server information by using the control unit 11 and the transmitter / receiver 13. The control unit 11 and the transmitter / receiver 13 correspond to the first server receiving unit.

In step 7, the first server 7 included in the first server group 3B sets the resolution improvement range 29 by using the control unit 11. An example of the resolution improvement range 29 is shown in FIG. The resolution improvement range 29 is a part of the detectable range 23B and is a range including the arrival position 27. The resolution improvement range 29 is, for example, a range narrower than the entire detectable range 23B.

The first server 7 included in the first server group 3B has a sensor unit 9 included in the first server group 3B that can detect the moving body 21 in at least a part of the resolution improvement range 29. The sensor instruction is transmitted by using the control unit 11 and the transmitter / receiver 13. The sensor instruction is an instruction to increase the temporal and spatial resolution of the sensor 15 in the resolution improvement range 29 in the time zone including the estimated arrival time to be higher than the normal temporal and spatial resolution.

Increasing the temporal resolution means shortening the cycle of the detection process periodically executed by the sensor 15. The normal temporal and spatial resolutions are temporal and spatial resolutions when the first server 7 included in the first server group 3B does not receive the second server information and does not transmit the sensor instruction. .. The control unit 11 and the transmitter / receiver 13 correspond to the sensor instruction transmission unit. Upon receiving the sensor instruction, the sensor unit 9 enhances the temporal and spatial resolution of the sensor 15 in response to the sensor instruction.

In step 8, the first server 7 included in the first server group 3B uses the control unit 11 to calculate the error. The error includes a spatial error and a temporal error. The spatial error is an error between the arrival position 27 and the actual arrival position. The actual arrival position is the position where the moving body 21 actually reaches the detectable range 23B.

The time error is an error between the estimated arrival time and the time when the moving body 21 actually reaches the detectable range 23B. The first server 7 included in the first server group 3B actually reaches the actual arrival position and the moving body 21 is within the detectable range 23B based on the sensor information sent from the sensor unit 9 included in the first server group 3B. You can get the time of arrival. The control unit 11 corresponds to the error calculation unit.
In step 9, the first server 7 included in the first server group 3B transmits the error information to the second server 5 by using the control unit 11 and the transmitter / receiver 13. The error information is information representing the error calculated in step 8. The control unit 11 and the transmitter / receiver 13 correspond to the error information transmission unit.

In step 10, the second server 5 receives the error information. The second server 5 corresponds to the second server receiving unit.
In step 11, the second server 5 modifies the estimation conditions of the arrival position 27 and the estimated arrival time so that the error is reduced based on the error information received in the step 10. The second server 5 corresponds to the modification unit.

4. Effects of the moving object detection system 1 (1A) The moving object detection system 1 enhances the temporal and spatial resolution of the sensor 15 in the resolution improvement range 29 in the time zone including the estimated arrival time. Therefore, the moving body detection system 1 can improve the detection accuracy of the moving body 21.

(1B) In the example shown in FIG. 1, the detectable range 23A and the detectable range 23B partially overlap. In this case as well, the moving body detection system 1 can improve the detection accuracy of the moving body 21.

(1C) The moving body detection system 1 modifies the estimation conditions of the arrival position 27 and the estimated arrival time so that the error is reduced based on the error information. Therefore, the mobile body detection system 1 can more accurately predict the arrival position 27 and the estimated arrival time.
<Second Embodiment>
1. 1. Configuration of Mobile Detection System 101 The configuration of the mobile detection system 101 will be described with reference to FIG. The mobile detection system 101 includes a server 107 and a plurality of sensor units 109A and 109B. The sensor units 109A and 109B can communicate with the server 107, respectively. In the present embodiment, the mobile detection system 101 includes two sensor units 109A and 109B, but the number of sensor units is not particularly limited and may be 3 or more.

The server 107 includes a control unit 111 and a transmitter / receiver 113. The control unit 111 includes a macro computer. The transmitter / receiver 113 can transmit / receive information to / from the sensor units 109A and 109B.

The sensor units 109A and 109B have a similar configuration. Here, the sensor unit 109A will be described. The sensor unit 109A is arranged on the road or at a position facing the road. The sensor unit 109A is mounted on a vehicle, for example. The sensor unit 109A includes a sensor 115, a control unit 117, and a transmitter / receiver 119.

The sensor 115 detects a moving object and generates sensor information. The sensor information is information representing the position of the moving body. Examples of the moving body include a vehicle, a walking vehicle, a bicycle, and the like. The sensor 115 is, for example, a camera, a rider, a millimeter wave radar, a sonar, or the like. The control unit 117 includes a microcomputer. The transmitter / receiver 119 can transmit / receive information to / from the server 107.

The sensor information will be described with reference to FIG. The detection range 123A is a range in which the sensor 115 of the sensor unit 109A can detect a moving body. The detection range 123B is a range in which the sensor 115 of the sensor unit 109B can detect a moving body.

The sensor information generated by the sensor 115 of the sensor unit 109A is information representing the existence probability of a moving body for each of the plurality of grids 31. For example, when the existence probability of a moving body on an arbitrary grid 31 is X, the probability that a moving body exists on the grid 31 is X. The grid 31 is set over the entire detection range 123A.

The sensor information generated by the sensor 115 of the sensor unit 109B is information representing the existence probability of a moving body for each of the plurality of grids 31. For example, when the existence probability of a moving body on an arbitrary grid 31 is X, the probability that a moving body exists on the grid 31 is X. The grid 31 is set over the entire detection range 123B.

2. Processing executed by the mobile detection system 101 The processing executed by the mobile detection system 101 will be described with reference to FIGS. 6, 8 and 9. In step 21 of FIG. 6, the sensor 115 included in the sensor unit 109A executes a process of detecting a moving body. When a moving object is detected, the sensor 115 generates sensor information.

In step 22, the sensor 115 included in the sensor unit 109B executes a process of detecting a moving object. When a moving object is detected, the sensor 115 generates sensor information.
In step 23, the sensor unit 109A transmits the sensor information to the server 107 by using the control unit 117 and the transmitter / receiver 119. The control unit 117 and the transmitter / receiver 119 correspond to the sensor information transmission unit.

In step 24, the sensor unit 109B transmits the sensor information to the server 107 by using the control unit 117 and the transmitter / receiver 119. The control unit 117 and the transmitter / receiver 119 correspond to the sensor information transmission unit.

In step 25, the server 107 receives the sensor information transmitted by the sensor units 109A and 109B by using the control unit 111 and the transmitter / receiver 113. The control unit 111 and the transmitter / receiver 113 correspond to the server receiving unit.

In step 26, the server 107 uses the control unit 111 to weight the plurality of sensor information received in step 25. The weight attached to the sensor information becomes smaller as the position of the moving body represented by the sensor information is closer to the boundary between the detection ranges 123A and 123B of the sensor 115. The position of the moving body represented by the sensor information is the position of the grid 31 having the highest probability of existence of the moving body among the plurality of grids 31 in the sensor information. The control unit 111 corresponds to the weighting setting unit.

In step 27, the server 107 uses the control unit 111 to set the sizes of the plurality of grids 31 in the sensor information. The control unit 111 corresponds to the grid setting unit. The method of setting the size of the plurality of grids 31 in the sensor information is as follows.

The server 107 determines whether or not the specific grid 31C exists in the plurality of grids 31 in the sensor information. The specific grid 31C is a grid 31 that has a relatively high probability of existence of a moving body and is located near the boundary of the detection range of the sensor 115.

In the example shown in FIG. 9, the specific grid 31C exists. The specific grid 31C is a part of the grid 31 included in the sensor information generated by the sensor unit 109A. In the specific grid 31C, the existence probability of the moving body 21 is relatively high. Further, the specific grid 31C is located near the boundary of the detection range 123A.

Further, the specific grid 31C shown in FIG. 9 is also a part of the grid 31 included in the sensor information generated by the sensor unit 109B. In the specific grid 31C, the existence probability of the moving body 21 is relatively high. Further, the specific grid 31C is located near the boundary of the detection range 123B.

The server 107 sets a specific range 33 in the grid 31 included in the sensor information generated by the sensor unit 109A. The specific range 33 is a range including the specific grid 31C and the grid 31 around the specific grid 31C. The server 107 sets the grid 31 included in the specific range 33 to be smaller than the grid 31 outside the specific range 33.

Further, the server 107 sets a specific range 33 in the grid 31 included in the sensor information generated by the sensor unit 109B. The specific range 33 is a range including the specific grid 31C and the grid 31 around the specific grid 31C. The server 107 sets the grid 31 included in the specific range 33 to be smaller than the grid 31 outside the specific range 33.

In the case shown in FIG. 8, the specific grid 31C does not exist. The server 107 sets all the grids 31 included in the sensor information generated by the sensor unit 109A to be larger than the grids 31 included in the specific range 33. Further, the server 107 sets all the grids 31 included in the sensor information generated by the sensor unit 109B to be larger than the grids 31 included in the specific range 33.

Returning to FIG. 6, in step 28, the server 107 estimates the position of the moving body based on the plurality of sensor information by using the control unit 111. The control unit 111 corresponds to the position estimation unit. The plurality of sensor information used when estimating the position of the moving body is the one in which the size of the grid 31 is set by the process of step 27. The server 107 estimates the position of the moving body using the weighting set in step 26.

Specific methods for estimating the position of the moving body are, for example, the following methods. From the sensor information, the existence probability Y (P) of the moving body in the grid 31 corresponding to the arbitrary position P is read out. The weighted existence probability Y (P) k is calculated by multiplying the read existence probability Y (P) by the weighting coefficient k. The weighting coefficient k increases as the weighting set in the sensor information in step 26 increases.

The weighted existence probability Y (P) k is calculated in the same manner for all the sensor information having the grid 31 corresponding to the position P. By multiplying all the weighted existence probabilities Y (P) k, the existence probability of the moving body at the position P is calculated. By calculating the existence probability of the moving body in the same manner for each position P, the distribution of the existence probability for each position can be obtained. The position with the highest existence probability is the position of the moving body.

In step 29, the server 107 uses the control unit 111 and the transmitter / receiver 113 to transmit the position of the moving body estimated in step 28. The transmission destination is, for example, sensor units 109A and 109B, an external device, and the like.

3. 3. Effect of the moving body detection system 101 (2A) The closer the position of the moving body is to the boundary between the detection ranges 123A and 123B, the lower the accuracy of the position of the moving body represented by the sensor information. In the moving body detection system 101, the closer the position of the moving body represented by the sensor information is to the boundary between the detection ranges 123A and 123B, the smaller the weighting of the sensor information is. Therefore, the moving body detection system 101 can accurately estimate the position of the moving body.

(2B) Generally, the closer the position of the moving body is to the boundary between the detection ranges 123A and 123B, the lower the detection accuracy of the moving body. In the moving body detection system 101, when the specific grid 31C exists, the size of the grid 31 in the specific range 33 is set smaller than that when the specific grid 31 does not exist. Therefore, the moving body detection system 101 can improve the detection accuracy of the moving body near the boundary between the detection ranges 123A and 123B. Further, the calculation load of the server 107 can be reduced as compared with the case where all the grids 31 are made smaller.

(2C) The sensor units 109A and 109B are mounted on a vehicle, for example. In this case, the sensor units 109A and 109B can detect moving objects existing around the vehicle.
(2D) The sensor units 109A and 109B are installed on the road, for example. In this case, the sensor units 109A and 109B can detect moving objects existing around the road.
<Other embodiments>
Although the embodiments of the present disclosure have been described above, the present disclosure is not limited to the above-described embodiments, and can be implemented in various modifications.

(1) In the second embodiment, in the process of step 28, the process of estimating the position of the moving body may be executed twice in some cases. In the first process, for example, the sizes of the grid 31 in the sensor information are all equal and large, as shown in FIG. If it is found that the specific grid 31 exists as a result of the first process, the second process is executed. In the second process, the size of the grid 31 in the sensor information is smaller in the specific range 33 than in the first process, and is the same as in the first process except in the specific range 33. If it is found that the specific grid 31 does not exist as a result of the first processing, the process ends without performing the second processing.

(2) In the second embodiment, as shown in FIG. 9, the size of the grid 31D, which has a relatively small existence probability of the moving body, may be larger than that of the other grids 31. In this case, the computational load on the server 107 can be further reduced.

(3) In the second embodiment, the processing of the step 26 may be performed by the sensor units 109A and 109B. In this case, the sensor units 109A and 109B weight the sensor information before transmitting the sensor information. The sensor information includes the result of weighting. In this case, the processing load on the server 107 can be reduced.

(4) In the second embodiment, the process of step 26 may not be executed, and the weighting of all sensor information may be the same.
(5) In the process of step 27 of the second embodiment, the sizes of all grids 31 may be constant regardless of the presence or absence of the specific grid 31C.

(6) The control units 11, 17, 111, 117 and the method thereof described in the present disclosure constitute a processor and a memory programmed to execute one or a plurality of functions embodied by a computer program. It may be realized by a dedicated computer provided by the above. Alternatively, the controls 11, 17, 111, 117 and methods thereof described in the present disclosure may be realized by a dedicated computer provided by configuring the processor with one or more dedicated hardware logic circuits. Alternatively, the controls 11, 17, 111, 117 and methods thereof described in the present disclosure consist of a processor and memory programmed to perform one or more functions and one or more hardware logic circuits. It may be realized by one or more dedicated computers configured in combination with the above-mentioned processors. The computer program may also be stored on a computer-readable non-transitional tangible recording medium as an instruction executed by the computer. The method of realizing the functions of each part included in the control units 11, 17, 111, and 117 does not necessarily include software, and all the functions are realized by using one or more hardware. May be done.

(7) A plurality of functions possessed by one component in the above embodiment may be realized by a plurality of components, or one function possessed by one component may be realized by a plurality of components. .. Further, a plurality of functions possessed by the plurality of components may be realized by one component, or one function realized by the plurality of components may be realized by one component. Further, a part of the configuration of the above embodiment may be omitted. In addition, at least a part of the configuration of the above embodiment may be added or replaced with the configuration of the other above embodiment.

(8) In addition to the above-mentioned mobile body detection system, a higher-level system having the mobile body detection system as a component, a program for operating a computer as the control units 11, 17, 111, 117, and this program are recorded. The present disclosure can also be realized in various forms such as a non-transitional actual recording medium such as a semiconductor memory, a moving object detection method, and the like.

1 ... Mobile detection system, 3A, 3B ... 1st server group, 5 ... 2nd server, 7 ... 1st server, 9 ... Sensor unit, 11 ... Control unit, 13 ... Transmitter, 15 ... Sensor, 17 ... Control Unit, 19 ... Transmitter, 21 ... Moving object, 23A, 23B ... Detectable range, 25 ... Future path, 29 ... Resolution improvement range, 31 ... Grid, 31C ... Specific grid, 31D ... Grid, 33 ... Specific range, 101 ... Mobile detection system, 107 ... Server, 109A, 109B ... Sensor unit, 111 ... Control unit, 113 ... Transmitter, 115 ... Sensor, 117 ... Control unit, 119 ... Transmitter, 123A, 123B ... Detection range

Claims (8)

It has a plurality of first server groups and a second server.
The first server group is a mobile detection system including a first server and a plurality of sensor units capable of communicating with the first server.
The sensor unit is arranged on the road or at a position facing the road.
The sensor unit is
A sensor configured to detect the position of a moving body and generate sensor information representing the position of the moving body.
A sensor information transmission unit configured to transmit the sensor information to the first server is provided.
The first server is
A first server receiving unit configured to receive a plurality of the sensor information from the plurality of the sensor units, and a first server receiving unit.
A position estimation unit configured to estimate the position of the moving body based on the plurality of sensor information received by the first server receiving unit, and a position estimation unit.
A first server information transmission unit configured to transmit the first server information representing the position of the moving body estimated by the position estimation unit to the second server is provided.
The second server
A second server receiving unit configured to receive the first server information from the first server, and
A route estimation unit configured to predict a future route of the mobile based on the first server information received by the second server receiving unit, and a route estimation unit.
Based on the future path of the moving body estimated by the route estimation unit, it is configured to estimate the arrival position at which the moving body reaches the detectable range of the moving body in any of the first server groups. The arrival position estimation unit and
Second server information transmission configured to transmit the second server information including the arrival position to the first server included in the first server group corresponding to the arrival position estimated by the arrival position estimation unit. With the unit
With
The first server receiving unit is configured to receive the second server information.
When the first server receives the second server information, the first server increases the temporal or spatial resolution of the sensor in the range including the arrival position as compared with the case where the second server information is not received. A sensor instruction unit that instructs the sensor unit is provided.
Mobile detection system. The mobile detection system according to claim 1.
The detectable range in the first server group including the first server that transmitted the first server information used by the route estimation unit to estimate the future route of the mobile body, and the second server information. Partially overlaps with the detectable range in the first server group including the first server that received the above.
Mobile detection system. The mobile detection system according to claim 1 or 2.
The first server is
An error calculation unit configured to calculate an error between the arrival position included in the second server information and the actual arrival position.
An error information transmission unit configured to transmit error information including the error to the second server is further provided.
The second server receiving unit is configured to receive the error information.
The second server further includes a correction unit configured to correct the estimation condition of the arrival position based on the error information so that the error is reduced.
Mobile detection system. A mobile detection system including a plurality of sensor units and a server capable of communicating with the sensor units.
The sensor unit is
A sensor configured to detect the position of a moving object,
A sensor information transmission unit configured to create sensor information representing the position of the moving body based on the detection result of the sensor and transmit the sensor information to the server is provided.
The server
A server receiving unit configured to receive a plurality of the sensor information from the plurality of the sensor units, and a server receiving unit.
A position estimation unit configured to weight each of the plurality of sensor information received by the server receiving unit and estimate the position of the moving body based on the weighted plurality of the sensor information is provided. ,
The server or the sensor unit is a weighting setting unit configured to set the weighting of the sensor information smaller as the position of the moving body represented by the sensor information is closer to the boundary of the detection range of the sensor. Prepare,
The position estimation unit is configured to estimate the position of the moving body using the weighting set by the weighting setting unit.
Mobile detection system. The mobile detection system according to claim 4.
The sensor unit includes the weighting setting unit.
Mobile detection system. A mobile detection system including a plurality of sensor units and a server capable of communicating with the sensor units.
The sensor unit is
A sensor configured to detect the position of a moving object,
A sensor information transmission unit configured to create sensor information representing the existence probability of the moving body for each of the plurality of grids based on the detection result of the sensor and transmit the sensor information to the server is provided. ,
The server
A server receiving unit configured to receive a plurality of the sensor information from the plurality of the sensor units, and a server receiving unit.
A grid setting unit configured to set the size of the grid in the sensor information, and
The position of the moving body is estimated by calculating the existence probability of the moving body for each of the plurality of the grids by using the plurality of sensor information having the size of the grid set by the grid setting unit. With a position estimation unit configured to
When the grid setting unit has a relatively high existence probability and a specific grid located near the boundary of the detection range of the sensor exists in the grid, the size of the grid in the range including the specific grid is large. Is set smaller than when the specific grid does not exist.
Mobile detection system. The mobile detection system according to any one of claims 4 to 6.
At least a part of the sensor unit is mounted on the vehicle.
Mobile detection system. The mobile detection system according to any one of claims 4 to 7.
At least a part of the sensor unit is installed on the road,
Mobile detection system.

Images