JP7138545B2 - Track integration device, track integration management device, track integration program and track integration management program - Google Patents

Description

TECHNICAL FIELD The present invention relates to a technique for knowing the track of a target.

There are detection data integration method, track integration method, and partial track integration method as methods for tracking a target using a plurality of sensors connected by a network.
The detection data integration method is a method of integrating detection data obtained by sensors.
The track integration method is a method for integrating track data.
The partial track integration method is a method of integrating partial track data obtained by tracking for a certain period of time based on detection data. The partial track data is track data in which the amount of data is compressed.
Track data integrated based on correlation is called integrated track data.

In the partial track integration method, a sensor network device is mounted on a sensor node.
At each sensor node, a sensor network device generates local track data based on observations obtained from the sensors. The sensor network device then exchanges partial track data obtained by fragmenting the local track data with other sensor network devices via the network. The sensor network device then integrates the partial track data based on the correlation to generate integrated track data.

In the partial track integration method, a destination selector that dynamically groups sensor nodes according to the course of a target enables partial track data to be transmitted and received only between sensor nodes that contribute to dealing with the target. As a result, unnecessary communication is suppressed and the amount of communication is reduced.

JP 2017-161323 A

In order to further reduce the amount of communication, it is conceivable to remove from the group sensor nodes that do not contribute to improving the accuracy of the track based on accuracy and data rate. However, the sensor node removed from the group cannot determine whether the detected target is a new target or a target whose track has already been registered and a group has been created. Therefore, each time a target is detected, an interrogation communication is required. As a result, it becomes difficult to further reduce the amount of communication.

The present invention enables partial track data to be sent and received only between sensor nodes that contribute to target handling without each sensor node inquiring about the detected target each time a target is detected by each sensor node. With the goal.

The track integrator of the present invention communicates with a master node and one or more sensor nodes.
The master node is a node that elects a group of nodes based on one or more partial track data, each representing a portion of the track.
Each sensor node is a node that generates integrated track data obtained by integrating one or more partial track data.
The track integration device is
a list acquisition unit that transmits partial track data to the master node and receives a node list indicating node groups from the master node;
a partial track notification unit that transmits partial track data to each sensor node included in the node group indicated in the received node list.

According to the present invention, each sensor node (track integrator) can obtain a node list by sending partial track data without communicating to query for targets.
Therefore, it is possible to send and receive partial track data only between sensor nodes that contribute to target handling without each sensor node inquiring about the detected target each time a target is detected by each sensor node.

1 is a configuration diagram of a track integration system 100 according to Embodiment 1. FIG. 2 is a configuration diagram of a sensor node 110 according to Embodiment 1. FIG. 2 is a hardware configuration diagram of a track integrating device 200 according to Embodiment 1. FIG. 2 is a configuration diagram of a master node 120 according to Embodiment 1. FIG. 2 is a hardware configuration diagram of a track integrated management device 300 according to Embodiment 1. FIG. 4 is a flowchart of a track integration method (tracking) according to Embodiment 1; 4 is a flowchart of a track integration method (tracking) according to Embodiment 1; 4 is a flowchart of a track integration method (local transmission request) according to Embodiment 1; 4 is a flowchart of a track integration method (remote transmission request) according to Embodiment 1; 4 is a flowchart of a track integration method (transmission control) according to Embodiment 1; 4 is a flowchart of a track integration method (integrated track) according to Embodiment 1; 4 is a flowchart of a track integration method (transmission) according to Embodiment 1; 4 is a flowchart of a track integration method (remote track reception) according to Embodiment 1; 4 is a flowchart of a track integration method (remote track reception) according to Embodiment 1; 4 is a flowchart of a track integration method (node list reception) according to Embodiment 1; 4 is a flow chart of a route integrated management method (destination selection) according to Embodiment 1; 4 is a flow chart of a route integrated management method (destination selection) according to Embodiment 1; 4 is a flow chart of a route integrated management method (change of destination) according to Embodiment 1; FIG. 2 is a configuration diagram showing features of a track integrating device 200 according to Embodiment 1; FIG. FIG. 2 is a configuration diagram showing features of a track integrated management device 300 according to Embodiment 1; FIG.

The same or corresponding elements are denoted by the same reference numerals in the embodiments and drawings. Descriptions of elements having the same reference numerals as those described will be omitted or simplified as appropriate. Arrows in the figure mainly indicate the flow of data or the flow of processing.

Embodiment 1.
The track integration system 100 will be described based on FIGS. 1 to 20. FIG.

*** Configuration description ***
The configuration of the track integration system 100 will be described based on FIG.
The track integration system 100 is a system for tracking a moving object and knowing the track of the moving object.
A specific example of a mobile object is a ship or an aircraft.
A track is a route taken by a moving object or information indicating the route.

The track integration system 100 includes multiple sensor nodes 110 and a master node 120 .

The plurality of sensor nodes 110 includes two types of sensor nodes 110, a sensor node 110L and a sensor node 110H.
The sensor node 110L has a longer detection range than the sensor node 110H and a lower data rate than the sensor node 110H.
The sensor node 110H has a shorter detection range than the sensor node 110L and a higher data rate than the sensor node 110L.
In FIG. 1, each of the sensor nodes 110a and 110c is the sensor node 110L, and each of the sensor nodes 110b and 110n is the sensor node 110H.

Each sensor node 110 communicates with other sensor nodes 110 and master node 120 via network 101 .
Specifically, each sensor node 110 communicates partial track data 102 to the other sensor nodes 110 and to the master node 120 .
The partial track data 102 indicates a portion of the track (partial track).

Master node 120 communicates with multiple sensor nodes 110 via network 101 .
Specifically, the master node 120 transmits the node list 103 to each sensor node 110 . Master node 120 also transmits network integrated track data 322 to backup nodes.
The node list 103 indicates node groups. A node group is one or more sensor nodes 110 that track the same target.
Network integrated track data 322 includes integrated track information. Integrated track information indicates an integrated track. An integrated track is obtained by integrating one or more partial tracks.
A spare node is a sensor node 110 that has become a spare member. Reserve members will be described later.

The configuration of the sensor node 110 will be described based on FIG.
A sensor node 110 includes a sensor 111 and a track integration device 200 .

A sensor 111 periodically measures the position of the mobile object. A specific example of sensor 111 is radar.

The track integration device 200 includes a correlator 201 , a reception manager 203 , a destination processor 206 , a local track generator 210 and a network track generator 220 . These elements are realized by software.
The local track generation unit 210 includes a tracking unit 211 , a transmission control unit 212 and an integration unit 213 .
The network track generation unit 220 includes a tracking unit 221 , a transmission control unit 222 and an integration unit 223 .

The track integrating device 200 includes a reception unit 202 , a communication unit 204 and a display unit 205 . These elements are realized by software and hardware.
The reception unit 202 receives input from the operator 112 .
A communication unit 204 communicates the partial track data 102 and the like.
The display unit 205 displays the track of the moving object.

The track integration device 200 includes a local integrated track storage unit 231, a local partial track storage unit 232, a network partial track storage unit 233, a request storage unit 234, a network integrated track storage unit 235, and a destination storage unit 236. Prepare. These elements are implemented by memory devices.

The hardware configuration of the track integrating device 200 will be described based on FIG.
The track integrating device 200 is a computer having hardware such as a processor 291 , a memory 292 , an auxiliary storage device 293 , a communication device 294 , a display device 295 and an input device 296 . The processor 291 is connected to other hardware via signal lines.

The processor 291 is an IC (Integrated Circuit) that performs processing and controls other hardware. Specifically, the processor 291 is a CPU, DSP or GPU. CPU is an abbreviation for Central Processing Unit. DSP is an abbreviation for Digital Signal Processor. GPU is an abbreviation for Graphics Processing Unit.
Memory 292 is a volatile storage device. Memory 292 is also called main storage or main memory. Specifically, the memory 292 is a RAM (Random Access Memory).
Auxiliary storage device 293 is a non-volatile storage device. Specifically, the auxiliary storage device 293 is a ROM, HDD, or flash memory. ROM is an abbreviation for Read Only Memory. HDD is an abbreviation for Hard Disk Drive.
Communication device 294 is a receiver and transmitter. Specifically, the communication device 294 is a communication chip or NIC (Network Interface Card).
The display device 295 is a display for displaying data. Specifically, the display device 295 is a liquid crystal display.
The input device 296 is a device for accepting data. Specifically, the input device 296 is a keyboard, mouse, touch panel, or the like.

Auxiliary storage device 293 stores a track integration program for causing a computer to execute the functions of track integration device 200 . The track integration program is loaded into memory 292 and executed by processor 291 .
Furthermore, the auxiliary storage device 293 stores an OS (Operating System). At least part of the OS is loaded into memory 292 and executed by processor 291 .
That is, the processor 291 executes the track integration program while executing the OS.
Data obtained by executing the track integration program is stored in storage devices such as memory 292 , auxiliary storage device 293 , registers within processor 291 or cache memory within processor 291 . These storage devices function as storage units that store data.
Note that the track integration device 200 may include a plurality of processors that substitute for the processor 291, and the plurality of processors may cooperate to execute the track integration program.

A communication device 294 is used to implement the functions of the communication unit 204 .
A display device 295 is used to realize the function of the display unit 205 .
The input device 296 is used to implement the functions of the reception unit 202 .

Hardware that functions as the processor 291, memory 292, and auxiliary storage device 293 is called "processing circuitry."
"Department" may be read as "processing" or "process". The functions of the track integrator 200 may be implemented in firmware.
The track integration program can be stored in a non-volatile storage medium such as magnetic disk, optical disk or flash memory.

The configuration of the master node 120 will be described based on FIG.
The master node 120 has an integrated track management device 300 .

The track integrated management device 300 includes an integration section 302 and a destination selection section 304 . These elements are realized by software.

Track integrated management device 300 includes communication unit 301 , display unit 303 , and reception unit 305 . These elements are realized by software and hardware.
The communication unit 301 communicates the partial track data 102 and the like.
A display unit 303 displays the track of the moving object.
The reception unit 305 receives input from the operator 121 .

The track integrated management device 300 includes a network integrated track storage unit 311 and a destination storage unit 312 . These elements are implemented by memory devices.

The hardware configuration of the track integrated management device 300 will be described based on FIG.
The track integrated management device 300 is a computer having hardware such as a processor 391 , a memory 392 , an auxiliary storage device 393 , a communication device 394 , a display device 395 and an input device 396 . The processor 391 is connected to other hardware via signal lines.

A processor 391 is an IC that performs processing and controls other hardware. Specifically, the processor 391 is a CPU, DSP or GPU.
Memory 392 is a volatile storage device. Memory 392 is also called main storage or main memory. Specifically, memory 392 is a RAM.
Auxiliary storage device 393 is a non-volatile storage device. Specifically, the auxiliary storage device 393 is a ROM, HDD, or flash memory.
Communication device 394 is a receiver and transmitter. Specifically, communication device 394 is a communication chip or NIC.
Display device 395 is a display for displaying data. Specifically, the display device 395 is a liquid crystal display.
Input device 396 is a device for receiving data. Specifically, the input device 396 is a keyboard, mouse, touch panel, or the like.

The auxiliary storage device 393 stores an integrated track management program for causing the computer to execute the functions of the integrated track management device 300 . The track integration management program is loaded into memory 392 and executed by processor 391 .
Furthermore, the auxiliary storage device 393 stores an OS. At least part of the OS is loaded into memory 392 and executed by processor 391 .
That is, the processor 391 executes the integrated track management program while executing the OS.
Data obtained by executing the integrated track management program is stored in a storage device such as a memory 392 , an auxiliary storage device 393 , a register within the processor 391 or a cache memory within the processor 391 . These storage devices function as storage units that store data.
Note that the integrated track management device 300 may include a plurality of processors that substitute for the processor 391, and the processors may execute the integrated track management program in cooperation with each other.

A communication device 394 is used to implement the function of the communication unit 301 .
A display device 395 is used to realize the function of the display unit 303 .
The input device 396 is used to implement the functions of the reception unit 305 .

Hardware that functions as the processor 391, memory 392, and auxiliary storage device 393 is called "processing circuitry."
"Department" may be read as "processing" or "process". The functions of the track integrated management device 300 may be realized by firmware.
The integrated track management program can be stored in a nonvolatile storage medium such as a magnetic disk, optical disk, or flash memory.

***Description of operation***
The track integration method (tracking) will be described with reference to FIGS. 6 and 7. FIG.
The track integration method (tracking) is the procedure when observations are accepted.

Steps S101 to S103 are correlation processing.
In step S<b>101 , the correlation unit 201 receives observation data 241 output from the sensor 111 .
The observation data 241 is data containing observation values.
The observed value is information specifying the position of the mobile object observed by the sensor 111 . The specific observed values are coordinate values.

Next, the correlation unit 201 refers to each local integrated track data 242 stored in the local integrated track storage unit 231 .
Local integrated track data 242 includes integrated track information and integrated track numbers.
Integrated track information is data indicating an integrated track.
An integrated track is a track obtained by integrating one or more partial tracks.
The integrated track number is an identifier that identifies the integrated track.

Then, the correlation unit 201 obtains a correlation value between the observation value included in the observation data 241 and the local integrated track information included in each local integrated track data 242 .
A correlation value is a value indicating the degree of correlation. Specific correlation values are the error of the integrated track, the error of the observed value, and the shortest distance from the integrated track to the observation point.

In step S102, the correlation unit 201 uses the correlation value for each local integrated track data 242 to determine whether there is any local integrated track data 242 that correlates with the observed value.
If the observed value is correlated with any local integrated track data 242, the process proceeds to step S103. Observations that correlate with any of the locally integrated track data 242 are referred to as "tracking observations."
If the observed value has no correlation with any of the local integrated track data 242, the correlator 201 outputs the observed value and the process proceeds to steps S104 and S111. Observations that have no correlation with any local integrated track data 242 are referred to as "new observations."

In step S103, the correlation unit 201 acquires an integrated track number from the local integrated track data 242 correlated with the observed value, adds the acquired integrated track number to the observed value, and outputs the observed value and the integrated track number. .

Steps S<b>104 to S<b>106 are tracking processing by the tracking unit 211 of the local track generating unit 210 .
In step S<b>104 , the tracking unit 211 determines whether the local partial track data 243 corresponding to the observed value output from the correlating unit 201 is registered in the local partial track storage unit 232 .
Local partial track data 243 includes partial track information, partial track numbers, and integrated track numbers.
The partial track information is data indicating a partial track.
A partial track is a track that is calculated based on one or more observations.
A partial track number is an identifier that identifies a partial track.

The tracking unit 211 determines that the local partial track data 243 corresponding to the observed value is registered in the local partial track storage unit 232 when the following condition (1) is satisfied.
(1) The observation value is a tracking observation value, and the local partial track data 243 containing the same integrated track number as the integrated track number attached to the tracking observation value is registered in the local partial track storage unit 232 .

When either of the following conditions (2) and (3) is satisfied, the tracking unit 211 determines that the local partial track data 243 corresponding to the observed value is not registered in the local partial track storage unit 232. .
(2) The observed value is a tracking observation value, and the local partial track data 243 containing the same integrated track number as the integrated track number given to the tracking observed value is not registered in the local partial track storage unit 232 .
(3) The observed value is a new observed value.

If the local partial track data 243 corresponding to the observed value is registered in the local partial track storage unit 232, the process proceeds to step S105.
If the local partial track data 243 corresponding to the observed value is not registered in the local partial track storage unit 232, the process proceeds to step S106.

In step S105, the tracking unit 211 updates the partial track information included in the local partial track data 243 corresponding to the observed value using the observed value.
Specifically, the tracking unit 211 performs prediction processing and smoothing processing on the partial track information included in the local partial track data 243 and the observed values.
The prediction process is a conventional process of changing the wake in chronological order and calculating predicted values of position and velocity.
A smoothing process is a conventional process of estimating a true value using a predicted value and an observed value.

In step S<b>106 , the tracking unit 211 generates new local partial track data 243 and registers the generated local partial track data 243 in the local partial track storage unit 232 .

Specifically, the tracking unit 211 generates new local partial track data 243 as follows.
When the observed value output from the correlation unit 201 is a tracking observed value, the tracking unit 211 generates new local partial track data 243 including the tracking observed value as partial track information. Further, the tracking unit 211 generates a new partial track number and sets the generated new partial track number and the integrated track number added to the tracking observation value to the new local partial track data 243 .
If the observed value output from the correlation unit 201 is a new observed value, the tracking unit 211 generates new local partial track data 243 including the new observed value as partial track information. Further, the tracking unit 211 generates a new partial track number and sets the generated new partial track number to the new local partial track data 243 . In this case, no integrated track number is set in the new local partial track data 243 .

Steps S 111 to S 113 are tracking processing by the tracking unit 221 of the network track generating unit 220 .
In step S<b>111 , the tracking unit 221 determines whether the network partial track data 244 corresponding to the observed value output from the correlation unit 201 is registered in the network partial track storage unit 233 . The contents of the network partial track data 244 are the same as the contents of the local partial track data 243, and the determination method is the same as the method in step S104.
If the network partial track data 244 corresponding to the observed value is registered in the network partial track storage unit 233, the process proceeds to step S112.
If the network partial track data 244 corresponding to the observed value is not registered in the network partial track storage unit 233, the process proceeds to step S113.

In step S112, the tracking unit 221 updates the network partial track data 244 corresponding to the observed value using the observed value. The update method is the same as the method in step S105.

In step S<b>113 , the tracking unit 221 generates new network partial track data 244 . The generation method is the same as the method in step S106.
The tracking unit 221 then registers the generated network partial track data 244 in the network partial track storage unit 233 .

Based on FIG. 8, the track integration method (local transmission request) will be described.
The track integration method (local transmission request) is a procedure when the local transmission request 251 is accepted.

Step S201 is local transmission request reception processing.
In step S<b>201 , the receiving unit 202 receives the local transmission request 251 and outputs the received local transmission request 251 .
A local send request 251 is a send request from the operator 112 of the sensor node 110 .
The transmission request is data containing an integrated track number, an error upper limit L_Upper, and an error lower limit L_Lower.

Step S202 is a local transmission request storage process.
In step S<b>202 , the reception management unit 203 stores the received local transmission request 251 in the request storage unit 234 .

Step S203 is a local transmission request setting process.
In step S203, the reception manager 203 searches the local partial track storage unit 232 for the local partial track data 243 containing the integrated track number that is the same as the integrated track number included in the local transmission request 251. FIG.
The reception management unit 203 then sets a local transmission request 251 for the corresponding local partial track data 243 .

A track integration method (remote transmission request) will be described with reference to FIG.
The track integration method (remote transmission request) is the procedure when the remote transmission request 252 is accepted.

Step S211 is remote transmission request acceptance processing.
In step S<b>211 , when the remote transmission request 252 is transmitted from another sensor node 110 , the communication unit 204 receives the remote transmission request 252 .
The reception management unit 203 receives the remote transmission request 252 received by the communication unit 204 .

Step S212 is a remote transmission request storage process.
In step S<b>212 , reception management unit 203 stores remote transmission request 252 received in request storage unit 234 .

Step S213 is a target request selection process.
In step S 213 , reception manager 203 selects one of the types of transmission request from local transmission request 251 and remote transmission request 252 . The selected sending request is called a "target request".
Specifically, reception manager 203 selects the transmission request with the higher request level. For example, the degree of request is determined by the upper error limit included in the send request. The lower the error upper limit included in the transmission request, the higher the request. The request degree of the local transmission request 251 is the minimum error upper limit value for one or more local transmission requests 251 stored in the request storage unit 234 . The request degree of the remote transmission request 252 is the minimum error upper limit value for one or more remote transmission requests 252 stored in the request storage unit 234 .
The reception management unit 203 then reads out each of the selected types of transmission requests from the request storage unit 234 .

Step S214 is a target request setting process.
In step S214, the reception management unit 203 performs the following processing for each read target request.
Receipt management unit 203 searches network partial track storage unit 233 for network partial track data 244 containing the same integrated track number as the integrated track number included in the target request. Then, the reception management unit 203 sets the target request to the relevant network partial track data 244 .

Based on FIG. 10, the track integration method (transmission control) will be described.
The track integration method (transmission control) is a procedure for judging whether or not to transmit the local partial track data 243 .
The track integration method (transmission control) is periodically executed for each local partial track data 243 for which a local transmission request 251 is set among the local partial track data 243 stored in the local partial track storage unit 232. be.

In step S301, the transmission control unit 212 determines whether the local partial track data 243 is to be newly registered.
Specifically, the transmission control unit 212 determines whether the integrated track number is included in the local partial track data 243 . The local partial track data 243 that does not include the integrated track number is to be newly registered.
If the local partial track data 243 is to be newly registered, the process proceeds to S302.
If the local partial track data 243 is not subject to new registration, the process proceeds to S303.

In step S302, the transmission control unit 212 outputs the local partial track data 243 as a transmission target (partial track data 102).
The transmission control unit 212 then deletes the local partial track data 243 from the local partial track storage unit 232 .

In step S<b>303 , the transmission control unit 212 calculates the prediction error λ of the local integrated track data 242 corresponding to the local partial track data 243 .

Specifically, the transmission control unit 212 calculates the prediction error λ as follows.
The transmission control unit 212 searches the local integrated track storage unit 231 for the local integrated track data 242 containing the integrated track number that is the same as the integrated track number included in the local partial track data 243 .
Then, the transmission control unit 212 calculates the prediction error λ of the corresponding local integrated track data 242 .
Calculation of the prediction error λ means calculating an eigenvalue for the local integrated track data 242 from the error covariance matrix of the Kalman filter.

In step S<b>304 , the transmission control unit 212 acquires the error upper limit value L_Upper from the local transmission request 251 included in the local partial track data 243 .
Then, the transmission control unit 212 compares the prediction error λ with the error upper limit value L_Upper.
If the prediction error λ is greater than the upper error limit L_Upper, the process proceeds to step S305.
If the prediction error λ is equal to or less than the upper error limit L_Upper, the process proceeds to step S306.

In step S305, the transmission control unit 212 outputs the local partial track data 243 as a transmission target (partial track data 102).
The transmission control unit 212 then deletes the local partial track data 243 from the local partial track storage unit 232 .

In step S<b>306 , the transmission control unit 212 acquires the lower error limit L_Lower from the local transmission request 251 included in the local partial track data 243 .
Then, the transmission control unit 212 compares the prediction error λ with the lower error limit L_Lower.
If the prediction error λ is greater than the lower error limit L_Lower, the process proceeds to step S307.
If the prediction error λ is equal to or less than the lower error limit L_Lower, the transmission control unit 212 suspends transmission of the local partial track data 243 . In other words, the transmission control unit 212 does not output the local partial track data as a transmission target (partial track data 102).

In step S<b>307 , the transmission control unit 212 calculates the error improvement amount I of the local partial track data 243 .
The error improvement amount I is an amount by which the prediction error λ is improved when the local partial track data 243 is sent as the partial track data 102 .

In step S308, the transmission control unit 212 compares the error improvement amount I with the transmission threshold Λ. The transmission threshold Λ is a predetermined value.
If the error improvement amount I is greater than the transmission threshold Λ, the process proceeds to S309.
If the error improvement amount I is equal to or less than the transmission threshold Λ, the transmission control unit 212 suspends transmission of the local partial track data 243 . In other words, the transmission control unit 212 does not output the local partial track data as a transmission target (partial track data 102).

In step S309, the transmission control unit 212 outputs the local partial track data 243 as a transmission target (partial track data 102).
The transmission control unit 212 then deletes the local partial track data 243 from the local partial track storage unit 232 .

A track integration method (track integration) will be described with reference to FIG.
The track integration method (track integration) is a procedure for registering or updating the local integrated track data 242 .
The track integration method (track integration) is executed for each partial track data 102 output from the transmission control unit 212 by the track integration method (transmission control) of FIG. 10 (see steps S302, S305 and S309).

In step S311, the integration unit 213 determines whether the partial track data 102 is to be newly registered.
Specifically, integration unit 213 determines whether partial track data 102 includes an integrated track number. The partial track data 102 that does not include the integrated track number is the new registration target.
If the partial track data 102 is to be newly registered, the process proceeds to step S312.
If the partial track data 102 is not to be newly registered, the process proceeds to step S313.

In step S<b>312 , the integration unit 213 uses the partial track data 102 to generate new local integrated track data 242 and registers the generated local integrated track data 242 in the local integrated track storage unit 231 .

Specifically, the integration unit 213 generates new local integrated track data 242 as follows.
The integration unit 213 generates new local integrated track data 242 including the partial track information included in the partial track data 102 as integrated track information.
Further, the integration unit 213 generates a new integrated track number and sets the generated new integrated track number to the new local integrated track data 242 .
Note that the method of generating the integrated track number is standardized in the track integration system 100 . That is, each track integration device 200 assigns the same integrated track number to the same integrated track.

Then, the display unit 205 displays the contents of the local integrated track data 242 registered in the local integrated track storage unit 231 . Specifically, the display unit 205 displays the integrated track based on the integrated track information included in the local integrated track data 242, and the like.

In step S<b>313 , the integration unit 213 updates the integrated track information included in the local integrated track data 242 corresponding to the partial track data 102 using the partial track information included in the partial track data 102 .

Specifically, the integration unit 213 updates the integrated track information as follows.
The integration unit 213 searches the local integrated track storage unit 231 for local integrated track data 242 containing the same integrated track number as the integrated track number included in the partial track data 102 .
Then, the integration unit 213 performs integration processing on the integrated track information included in the relevant local integrated track data 242 and the partial track information included in the partial track data 102 .
The integration process is a conventional process that extrapolates the integrated track information up to the time when the partial track information is obtained, smoothes the error of the integrated track and the error of the partial track, and calculates the position of the integrated track. be.

Then, the display unit 205 displays the content of the updated local integrated track data 242 . Specifically, the display unit 205 displays the integrated track based on the integrated track information included in the updated local integrated track data 242, and the like.

Based on FIG. 12, the track integration method (transmission) will be described.
The track integration method (transmission) is a procedure for transmitting partial track data 102 to other sensor nodes 110 .
The track integration method (transmission) is performed periodically for each network partial track data 244 for which a local transmission request 251 or a remote transmission request 252 is set, out of the network partial track data 244 stored in the network partial track storage unit 233. executed as expected.

Step S401 is a transmission control process.
In step S401, the transmission control unit 222 determines whether or not the network partial track data 244 needs to be transmitted. The determination method is the same as the method in the track integration method (transmission control) of FIG.
The network partial track data 244 determined to require transmission is referred to as "partial track data 102".

Step S402 is first detection determination processing.
In step S402, the transmission control unit 222 determines whether the partial track indicated by the partial track data 102 is the first detected partial track.
Specifically, the transmission control unit 222 determines whether the integrated track number is set in the partial track data 102 . If the integrated track number is not set in the partial track data 102, the transmission control unit 222 determines that the partial track indicated by the partial track data 102 is the first detected partial track.
If the partial track indicated by the partial track data 102 is the first detected partial track, the process proceeds to step S403.
If the partial track indicated by the partial track data 102 is not the first detected partial track, the process proceeds to step S404.

In step S<b>403 , the transmission control unit 222 determines the master node 120 as the transmission destination of the partial track data 102 .
Then, the communication unit 204 transmits the partial track data 102 to the destination master node 120 .

In step S 404 , the transmission control unit 222 searches the destination storage unit 236 for the node list 247 containing the integrated track number that is the same as the integrated track number included in the partial track data 102 .
Node list 247 includes integrated track numbers and destination information.
The destination information indicates one or more sensor nodes 110 tracking the same target.
Details of the node list 247 will be described later.

In step S405, the transmission control unit 222 determines the search result.
If there is a node list 247 containing the integrated track number that is the same as the integrated track number included in the partial track data 102, the process proceeds to step S406.
If there is no node list 247 containing the same integrated track number as the integrated track number included in the partial track data 102, the process proceeds to step S408.

Step S406 is a reserve member determination process. Reserve members will be described later.
In step S406, the transmission control unit 222 determines whether or not its own node is a backup member.
If the own node is a spare member, the process proceeds to step S408.
If the own node is not a backup member, the process proceeds to step S407.

In step S<b>407 , the transmission control unit 222 determines one or more sensor nodes 110 shown in the node list 247 as destinations of the partial track data 102 .
Then, the communication unit 204 transmits the partial track data 102 to each sensor node 110 as a destination.

Step S408 is integration processing.
In step S<b>408 , the integration unit 223 updates or registers the network-integrated track data 246 using the partial track data 102 .
The method of updating or registering the network integrated track data 246 is similar to the method in the track integration method (track integration) of FIG.

The track integration method (remote track reception) will be described with reference to FIGS. 13 and 14. FIG.
The track integration method (remote track reception) is a procedure when partial track data 102 is transmitted from other sensor nodes 110 . The partial track data 102 are transmitted from other sensor nodes 110 in step S407 of the track integration method (transmission) (see FIG. 12).

Step S411 is remote partial track reception processing.
In step S<b>411 , the communication unit 204 receives the partial track data 102 and outputs the received partial track data 102 .
The partial track data 102 output from the communication unit 204 is referred to as "remote partial track data 245", and the partial track information included in the remote partial track data 245 is referred to as "remote partial track information".

Steps S<b>412 to S<b>415 are processing by the integration unit 213 of the local track generation unit 210 .
In step S<b>412 , the integration unit 213 obtains a correlation between the remote partial track data 245 and each local integrated track data 242 .
Specifically, the integration unit 213 obtains a correlation between the remote partial track information included in the remote partial track data 245 and the local integrated track information included in each local integrated track data 242 .
The method of obtaining the correlation is the same as the method in step S101 of the track integration method (tracking) (see FIG. 6).

In step S<b>413 , the integration unit 213 determines whether there is local integrated track data 242 that correlates with the remote partial track data 245 .
If there is local integrated track data 242 correlated with remote partial track data 245, processing proceeds to step S414.
If there is no local integrated track data 242 correlated with remote partial track data 245, processing proceeds to step S415.

In step S<b>414 , the integration unit 213 updates the local integrated track data 242 corresponding to the remote partial track data 245 using the remote partial track data 245 . The method of updating the local integrated track data 242 is the same as the method in step S313 of the track integration method (track integration) (see FIG. 11).

In step S<b>415 , the integration unit 213 uses the remote partial track data 245 to generate new local integrated track data 242 and registers the generated local integrated track data 242 in the local integrated track storage unit 231 . The method of generating the new local integrated track data 242 is the same as the method in step S312 of the track integration method (track integration) (see FIG. 11).

Steps S<b>421 to S<b>424 are processing by the integration unit 223 of the network track generation unit 220 .
In step S<b>421 , the integration unit 223 obtains a correlation between the remote partial track data 245 and each network integrated track data 246 .
Specifically, the integration unit 223 obtains a correlation between the remote partial track information included in the remote partial track data 245 and the network integrated track information included in each network integrated track data 246 .
The method of obtaining the correlation is the same as the method in step S101 of the track integration method (tracking) (see FIG. 6).

In step S<b>422 , the integration unit 223 determines whether there is network-integrated track data 246 that correlates with the remote partial track data 245 .
If there is network-integrated track data 246 correlated with remote partial track data 245, processing proceeds to step S423.
If there is no network-integrated track data 246 correlated with the remote partial track data 245, processing proceeds to step S424.

In step S<b>423 , the integration unit 223 updates the network-integrated track data 246 corresponding to the remote partial track data 245 using the remote partial track data 245 . The method of updating the network integrated track data 246 is the same as the method in step S313 of the track integration method (track integration) (see FIG. 11).

In step S<b>424 , the integration unit 223 uses the remote partial track data 245 to generate new network-integrated track data 246 and registers the generated network-integrated track data 246 in the network-integrated track storage unit 235 . The method of generating the new network integrated track data 246 is the same as the method in step S312 of the track integration method (track integration) (see FIG. 11).

Based on FIG. 15, the track integration method (node list reception) will be described.
The track integration method (node list reception) is a procedure when the node list 103 is transmitted from the master node 120 . The node list 103 is transmitted from the master node 120 in the route integrated management method (destination selection) described later (see FIGS. 16 and 17).

Step S501 is node list acceptance processing.
In step S<b>501 , the communication unit 204 receives the node list 103 and outputs the received node list 103 .
The node list 103 includes integrated track numbers and group information.
Group information indicates one or more sensor nodes 110 tracking the same target.

In step S502, the destination processing unit 206 searches the destination storage unit 236 for the node list 247 containing the integrated track number that is the same as the integrated track number included in the node list 103. FIG.

In step S503, the destination processing unit 206 determines the search result.
If there is no node list 247 containing the same integrated track number as the integrated track number included in the node list 103, the process proceeds to step S504.
If there is a node list 247 containing the same integrated track number as the integrated track number included in the node list 103, the process proceeds to step S505.

In step S<b>504 , destination processing unit 206 registers node list 103 as node list 247 in destination storage unit 236 .

In step S505, the destination processing unit 206 searches the node list 103 for its own node.

In step S506, the destination processing unit 206 determines the search result.
If the own node is included in the node list 103, the process proceeds to step S507.
If the own node is not included in the node list 103, the process proceeds to step S508.

In step S<b>507 , the destination processing unit 206 updates the node list 247 with the node list 103 .
That is, the destination processing unit 206 overwrites the node list 247 stored in the destination storage unit 236 with the received node list 103 .

In step S<b>508 , the destination processing unit 206 deletes the node list 247 from the destination storage unit 236 .

A route integrated management method (destination selection) will be described with reference to FIGS. 16 and 17. FIG.
The track integrated management method (destination selection) is a procedure when the master node 120 receives the partial track data 102 from the sensor node 110 . The partial track data 102 is transmitted from the sensor node 110 in step S403 of the track integration method (transmission) (see FIG. 12).

Step S601 is remote partial track reception processing.
In step S<b>601 , the communication unit 301 receives the partial track data 102 and outputs the received partial track data 102 .
The partial track data 102 output from the communication unit 301 is referred to as "remote partial track data 321", and the partial track information included in the remote partial track data 321 is referred to as "remote partial track information".

In step S<b>602 , the integration unit 302 obtains a correlation between the remote partial track data 321 and each network integrated track data 322 .
Specifically, the integration unit 302 obtains a correlation between the remote partial track information included in the remote partial track data 321 and the network integrated track information included in each network integrated track data 322 .
The method of obtaining the correlation is the same as the method in step S101 of the track integration method (tracking) (see FIG. 6).

In step S<b>603 , the integration unit 302 determines whether there is network-integrated track data 322 that correlates with the remote partial track data 321 .
If there is network-integrated track data 322 correlated with remote partial track data 321, the process proceeds to step S604.
If there is no network-integrated track data 322 correlated with the remote partial track data 321, the process proceeds to step S608.

In step S<b>604 , the integration unit 302 updates the network-integrated track data 322 corresponding to the remote partial track data 321 using the remote partial track data 321 . The method of updating the network integrated track data 322 is the same as the method in step S313 of the track integration method (track integration) (see FIG. 11).

Then, the display unit 303 displays the contents of the updated network-integrated track data 322 . Specifically, the display unit 303 displays the integrated track based on the network-integrated track information included in the updated network-integrated track data 322, and the like.

In step S605, the integration unit 302 determines whether at least part of the integrated track indicated by the updated network integrated track data 322 is within the coverage area of any sensor node 110H.
If at least part of the integrated track indicated by the updated network integrated track data 322 is within the coverage area of any sensor node 110H, the process proceeds to step S606.
If at least part of the integrated track indicated by the updated network integrated track data 322 is not within the coverage area of any sensor node 110H, the process proceeds to step S607.

In step S606, the destination selection unit 304 changes each sensor node 110 shown in the node list 103 from a group member to a backup member.
Reserve members are periodically sent network integrated track data 322 from the master node 120 . When determining that the target detected by the reserve member is the target detected by the sensor node 110H, the reserve member does not transmit the target information (partial track data 102).

In step S<b>607 , the destination selection unit 304 updates the node list 103 based on the updated network-integrated track data 322 .
Specifically, the destination selection unit 304 updates the node list 103 as follows.
The destination selection unit 304 searches the destination storage unit 312 for the node list 103 containing the integrated track number that is the same as the integrated track number included in the network integrated track data 322 .
The destination selection unit 304 performs prediction processing on the network-integrated track data 322 and determines whether or not there is an intersection between the predicted track and the coverage area of the sensor 111 provided in each sensor node 110 .
The prediction process is a conventional process of changing the wake in chronological order and calculating predicted values of position and velocity.
Then, the destination selection unit 304 updates the node list 103 as follows based on the node list 103 and the presence/absence of the intersection.
If there is an intersection between the predicted track and the coverage area of the sensor 111 provided in the sensor node 110 and the sensor node 110 is not included in the group information in the node list 103, the destination selection unit 304 selects the sensor node 110. Add to the group information in the node list 103 .
If there is no intersection between the predicted track and the coverage area of the sensor 111 provided in the sensor node 110 and the sensor node 110 is included in the group information in the node list 103, the destination selection unit 304 selects the sensor node 110 as a node. Delete from the group information in the list 103 .
If there is an intersection between the predicted track and the coverage area of the sensor 111 provided in the sensor node 110, and the sensor node 110 is included in the group information in the node list 103, the destination selection unit 304 selects do not change the group information of
If there is no intersection between the predicted track and the coverage area of the sensor 111 provided in the sensor node 110 and the sensor node 110 is not included in the group information in the node list 103, the destination selection unit 304 Do not change the group information inside.

In step S608, the destination selection unit 304 determines whether the node list 103 has been changed. Specifically, the destination selection unit 304 determines whether the group information in the node list 103 has been changed.
If the node list 103 has changed, the process advances to step S609.
If there is no change in the node list 103, the process ends.

In step S<b>609 , the destination selection unit 304 registers the updated node list 103 in the destination storage unit 312 .
Then, the communication unit 301 transmits the network-integrated track data 322, the partial track data 102, and the updated node list 103 as follows.
The communication unit 301 transmits the network integrated track data 322 to the sensor nodes 110 added to the node list 103 .
The communication unit 301 transmits the node list 103 and the partial track data 102 to each sensor node 110 included in the group information in the node list 103 . However, the communication section 301 does not transmit to the backup members.
The communication unit 301 transmits the node list 103 to the sensor nodes 110 deleted from the node list 103 .

In step S<b>611 , the integration unit 302 generates new network-integrated track data 322 using the partial track data 102 and registers the generated network-integrated track data 322 in the network-integrated track storage unit 311 . The method of generating the new network integrated track data 322 is the same as the method in step S312 of the track integration method (track integration) (see FIG. 11).

The display unit 303 displays the contents of the network-integrated track data 322 registered in the network-integrated track storage unit 311 . Specifically, the display unit 303 displays the integrated track based on the integrated track information included in the network integrated track data 322, and the like.

In step S<b>612 , the destination selection unit 304 generates the node list 103 based on the new network integrated track data 322 .
Specifically, the destination selection unit 304 generates the node list 103 as follows.
The destination selection unit 304 performs prediction processing on the new network-integrated track data 322 and determines whether or not there is an intersection between the predicted track and the coverage area of the sensor 111 provided in each sensor node 110 .
The prediction process is a conventional process of changing the wake in chronological order and calculating predicted values of position and velocity.
Then, the destination selection unit 304 generates the node list 103 as follows based on the presence or absence of the intersection.
If there is an intersection between the predicted track and the coverage area of the sensor 111 provided in the sensor node 110 , the destination selection unit 304 sets the sensor node 110 as group information in the node list 103 .
If there is no intersection between the predicted track and the coverage area of the sensor 111 included in the sensor node 110 , the destination selection unit 304 does not set the sensor node 110 as group information in the node list 103 .

Furthermore, the destination selection unit 304 sets the master node 120 in the group information in the node list 103 .

In step S<b>613 , the destination selection unit 304 adds the integrated track number of the new network integrated track data 322 to the node list 103 and registers the node list 103 in the destination storage unit 312 .
The communication unit 301 then transmits the node list 103 and the partial track data 102 to each sensor node 110 indicated by the group information in the node list 103 .

Based on FIG. 18, the route integrated management method (transmission destination change) will be described.
The track integration method (destination change) is a procedure when the operator 121 of the master node 120 inputs the destination change request 331 to the track integration management device 300 .

Step S621 is destination change request acceptance processing.
In step S<b>621 , the receiving unit 305 receives the destination change request 331 and outputs the received destination change request 331 .
A destination change request 331 is a request for changing a node group.
The destination change request 331 is data containing an integrated track number and a new node list.

In step S<b>622 , the destination selection unit 304 updates the node list 103 based on the destination change request 331 .
Specifically, destination selection unit 304 searches destination storage unit 312 for node list 103 that includes the same integrated track number as the integrated track number included in destination change request 331 .
Then, the destination selection unit 304 overwrites the group information in the node list 103 with the group information in the new node list included in the destination change request 331 .

In step S<b>623 , the destination selection unit 304 registers the updated node list 103 in the destination storage unit 312 .
The destination selection unit 304 searches the network-integrated track storage unit 311 for the network-integrated track data 322 containing the same integrated track number as the integrated track number included in the updated node list 103 .
Then, the communication unit 301 transmits the updated node list 103 and the network-integrated track data 322 as follows.
The communication unit 301 transmits the network integrated track data 322 to the sensor nodes 110 added to the group information in the node list 103 .
The communication unit 301 transmits the node list 103 and the network integrated track data 322 to the sensor nodes 110 indicated by the group information in the node list 103 .
The communication unit 301 transmits the node list 103 to the sensor nodes 110 deleted from the group information in the node list 103 .

***Description of Features***
Features of the track integrating device 200 will be described with reference to FIG. 19 .
The track integration device 200 includes a target tracking unit 281 , a track integration unit 282 , a list acquisition unit 283 and a partial track notification unit 284 .
Target tracking unit 281 is implemented by tracking unit 221 .
The track integrator 282 is implemented by the integrator 223 .
List acquisition unit 283 is implemented by destination processing unit 206 and communication unit 204 .
Partial track notification unit 284 is implemented by transmission control unit 222 and communication unit 204 .

The track integration program causes the computer to function as a target tracking unit 281 , a track integration unit 282 , a list acquisition unit 283 and a partial track notification unit 284 .

The track integration device 200 includes an integrated track storage unit 285 and a list storage unit 286 .
Integrated track storage unit 285 is implemented by network integrated track storage unit 235 .
List storage unit 286 is implemented by destination storage unit 236 .

A first feature of the track integrator 200 will be described.
Track integrator 200 communicates with master node 120 and one or more sensor nodes 110 .
A master node 120 is a node that elects a node group based on one or more partial track data. Each partial track data represents a portion of the track.
Each sensor node 110 produces integrated track data. Integrated track data is obtained by integrating one or more partial track data.
The list acquisition unit 283 transmits the partial track data to the master node 120 (see step S403 in FIG. 12) and receives the node list from the master node 120 (see step S501 in FIG. 15). A node list indicates a node group.
The partial track notification unit 284 transmits the partial track data to each sensor node 110 included in the node group indicated in the received node list (see step S407 in FIG. 12).

A feature (second feature) related to the first feature of the track integrating device 200 will be described.
The target tracking unit 281 generates partial track data.
The track integration unit 282 generates integrated track data. Integrated track data is obtained by integrating one or more partial track data.
Integrated track storage unit 285 stores one or more integrated track data.
The list storage unit 286 stores one or more node lists corresponding to the one or more integrated track data.
If the generated partial track data has no correlation with any of the one or more integrated track data, the list acquisition unit 283 transmits the generated partial track data to the master node 120 (see step S403 in FIG. 12). .
If the generated partial track data is correlated with any of the one or more integrated track data, the partial track notification unit 284 selects the generated partial track data among the one or more node lists. Refer to the node list corresponding to the integrated track data (see step S404 in FIG. 12). The partial track notification unit 284 then transmits the generated partial track data to each sensor node 110 included in the node group indicated in the referenced node list (see step S407 in FIG. 12).

A feature (third feature) related to the second feature of the track integrating device 200 will be described.
Each node list includes an integrated track identifier that identifies corresponding integrated track data.
If the integrated track data correlated with the generated partial track data is stored in the integrated track storage unit 285, the target tracking unit 281 adds an integrated track identifier for identifying the integrated track data to the generated partial track data. (see step S105 in FIG. 6).
If the generated partial track data does not include the integrated track identifier, the list acquisition unit 283 transmits the generated partial track data to the master node 120 (see step S403 in FIG. 12).
If the generated partial track data includes an integrated track identifier, the partial track notification unit 284 refers to the node list containing the same integrated track identifier as the integrated track identifier included in the generated partial track data (Fig. 12 (see step S404).

A feature (fourth feature) relating to the third feature of the track integrating device 200 will be described.
The track integration device 200 is provided in a sensor node 110 different from the one or more sensor nodes 110 .
The master node 120 generates a node list including the integrated track identifier and transmits the generated node list to each sensor node 110 included in the node group indicated in the generated node list (FIGS. 16 to 18). ).
When the generated node list is transmitted to the sensor node 110 provided with the track integrating device 200, the list acquisition unit 283 receives the generated node list (see step S501 in FIG. 15).
If the list storage unit 286 does not store a node list containing the same integrated track identifier as the integrated track identifier included in the received node list, the list acquisition unit 283 stores the received node list in the list storage unit 286. (see step S504 in FIG. 15).
If the list storage unit 286 stores a node list containing the same integrated track identifier as the integrated track identifier included in the received node list, the list acquisition unit 283 retrieves the node list stored in the list storage unit 286. is updated using the received node list (see step S507 in FIG. 15).

A feature (fifth feature) relating to the fourth feature of the track integrating device 200 will be described.
If the list storage unit 286 stores a node list containing the same integrated track identifier as the integrated track identifier included in the received node list, the list acquisition unit 283 retrieves the node list stored in the list storage unit 286. (see step S502 in FIG. 15).
If the node group indicated in the referenced node list includes the sensor node 110 including the track integrating device 200, the list acquisition unit 283 updates the referenced node list using the received node list ( (see step S507 in FIG. 15).
If the node group indicated in the referenced node list does not include the sensor node 110 having the track integrating device 200, the referenced node list is deleted (see step S508 in FIG. 15).

Features of the integrated track management device 300 will be described with reference to FIG. 20 .
The integrated track management device 300 includes a partial track reception unit 381 , a track integration unit 382 , a group selection unit 383 , a group designation unit 384 and a group change unit 385 .
Partial track reception unit 381 is implemented by communication unit 301 .
The track integrator 382 is implemented by the integrator 302 .
Group selection section 383 is implemented by destination selection section 304 .
Group designation unit 384 is implemented by communication unit 301 .
Group change unit 385 is implemented by reception unit 305 , destination selection unit 304 , and communication unit 301 .

The track integration management program causes the computer to function as a partial track reception unit 381 , a track integration unit 382 , a group selection unit 383 , a group designation unit 384 and a group change unit 385 .

The integrated track management device 300 includes an integrated track storage unit 386 and a list storage unit 387 .
Integrated track storage unit 386 is implemented by network integrated track storage unit 311 .
List storage unit 387 is implemented by destination storage unit 312 .

A first feature of the integrated track management device 300 will be described.
The partial track reception unit 381 receives one or more pieces of partial track data from the plurality of sensor nodes 110 (see step S601 in FIG. 16). Each partial track data represents a portion of the track.
The group selector 383 selects a node group based on the received one or more partial track data (see step S607 in FIG. 16 and step S612 in FIG. 17).
The group specifying unit 384 transmits a node list indicating the selected node group to each sensor node 110 included in the selected node group (see step S609 in FIG. 16 and step S613 in FIG. 17).

A feature (second feature) relating to the first feature of the track integrated management device 300 will be described.
Integrated track storage unit 386 stores one or more integrated track data. Each integrated track data is obtained by integrating one or more partial track data.
The list storage unit 387 stores one or more node lists corresponding to the one or more integrated track data.
When partial track data is received from any of the sensor nodes 110, the group selection unit 383 selects integrated track data correlated with the received partial track data from the one or more integrated track data (Fig. 16 step S603). Next, the group selection unit 383 selects a node group based on the selected integrated track data (see step S607 in FIG. 16). Also, the group selection unit 383 selects a node list corresponding to the selected integrated track data from the one or more node lists (see step S607 in FIG. 16). Then, the group selection unit 383 updates the selected node list based on the selected node group (see steps S607 to S609 in FIG. 16).

A feature (third feature) relating to the second feature of the track integrated management device 300 will be described.
Each node list includes an integrated track identifier that identifies corresponding integrated track data.
The group selection unit 383 selects a node list that includes the same integrated track identifier as the integrated track identifier that identifies the selected integrated track data (see step S607 in FIG. 16).

A feature (fourth feature) related to the second feature and the third feature of the track integrated management device 300 will be described.
Each sensor node 110 comprises a sensor 111 .
If the coverage area of the sensor 111 provided in the sensor node 110 includes at least part of the integrated track indicated by the integrated track data correlated with the received partial track data, the group selection unit 383 selects the node group includes the sensor node 110 (see step S607 in FIG. 16).
If the coverage area of the sensor 111 provided in the sensor node 110 does not include even a part of the integrated track indicated by the integrated track data correlated with the received partial track data, the group selection unit 383 selects the node The sensor node 110 is not included in the group (see step S607 in FIG. 16).

Features related to the second to fourth features (fifth feature) of the track integrated management device 300 will be described.
The track integration unit 382 updates integrated track data correlated with the received partial track data based on the received partial track data (see step S604 in FIG. 16).
The group selection unit 383 selects a node group based on the updated integrated track data (see step S607 in FIG. 16).

A feature (sixth feature) relating to the fifth feature of the track integrated management device 300 will be described.
If the integrated track data correlated with the received partial track data is not stored in the integrated track storage unit 386, the track integration unit 382 generates integrated track data based on the received partial track data (see FIG. 17). (see step S611 of ). The track integration unit 382 then stores the generated integrated track data in the integrated track storage unit 386 (see step S611 in FIG. 17).
The group selection unit 383 selects a node group based on the generated integrated track data (see step S612 in FIG. 17). Next, the group selection unit 383 generates a node list indicating the selected node groups (see step S612 in FIG. 17). Then, the group selection unit 383 stores the generated node list in the list storage unit 387 (see step S613 in FIG. 17).

A feature (seventh feature) relating to the sixth feature of the track integrated management device 300 will be described.
When the integrated track data is generated, the group selection unit 383 calculates the predicted track based on the generated integrated track data (see step S612 in FIG. 17).
If at least part of the calculated predicted track is included in the coverage area of the sensor 111 of the sensor node 110, the group selection unit 383 includes the sensor node 110 in the node group to be selected (step S612 in FIG. 17). reference).
If the sensor node 110 sensor coverage area does not include a part of the calculated predicted route, the group selection unit 383 does not include the sensor node 110 in the node group to be selected (step S612).

Features related to the first to seventh features (eighth feature) of the track integrated management device 300 will be described.
The group change unit 385 accepts a request to change the node group indicated in the node list (see step S621 in FIG. 18). Next, the group change unit 385 changes the node group indicated in the node list based on the accepted change request (see step S622 in FIG. 18). Then, the group changing unit 385 transmits the changed node list to each sensor node included in the node group indicated in the changed node list (see step S623 in FIG. 18).

*** Effect of Embodiment 1 ***
By reducing the number of sensor nodes 110 to which the partial track data 102 are communicated, the load on the network 101 can be reduced and the track of the moving object can be obtained by a plurality of track integrating devices 200 .

In addition, each sensor node 110 can obtain the node list 103 by sending partial track data 102 without communicating to inquire about targets.
Therefore, partial track data 102 can be sent and received only between sensor nodes 110 that contribute to target handling without each sensor node 110 querying the detected target each time a target is detected by each sensor node 110 . It becomes possible.

*** Supplement to the embodiment ***
The embodiments are examples of preferred modes and are not intended to limit the technical scope of the present invention. Embodiments may be implemented partially or in combination with other embodiments. The procedures described using flowcharts and the like may be changed as appropriate.

100 track integration system, 101 network, 102 partial track data, 103 node list, 110 sensor node, 111 sensor, 112 operator, 120 master node, 121 operator, 200 track integration device, 201 correlation unit, 202 reception unit, 203 reception management Unit, 204 Communication Unit, 205 Display Unit, 206 Destination Processing Unit, 210 Local Track Generation Unit, 211 Tracking Unit, 212 Transmission Control Unit, 213 Integration Unit, 220 Network Track Generation Unit, 221 Tracking Unit, 222 Transmission Control Unit, 223 integration unit 231 local integrated track storage unit 232 local partial track storage unit 233 network partial track storage unit 234 request storage unit 235 network integrated track storage unit 236 destination storage unit 241 observation data 242 local integration Track data, 243 Local partial track data, 244 Network partial track data, 245 Remote partial track data, 246 Network integrated track data, 247 Node list, 251 Local send request, 252 Remote send request, 281 Target tracker, 282 Track integration unit , 283 list acquisition unit, 284 partial track notification unit, 285 integrated track storage unit, 286 list storage unit, 291 processor, 292 memory, 293 auxiliary storage device, 294 communication device, 295 display device, 296 input device, 300 integrated track management device 301 communication unit 302 integration unit 303 display unit 304 destination selection unit 305 reception unit 311 network integrated track storage unit 312 destination storage unit 321 remote partial track data 322 network integrated track data 331 Destination change request, 381 partial track reception unit, 382 track integration unit, 383 group selection unit, 384 group designation unit, 385 group change unit, 386 integrated track storage unit, 387 list storage unit, 391 processor, 392 memory, 393 auxiliary Storage device, 394 communication device, 395 display device, 396 input device.

Claims (13)

A track integrator that communicates with a master node and one or more sensor nodes,
the master node is a node that selects a group of nodes based on one or more partial track data, each representing a portion of the track;
Each sensor node is a node that generates integrated track data obtained by integrating one or more partial track data,
The track integration device is
a list acquisition unit that transmits partial track data to the master node and receives a node list indicating node groups from the master node;
a partial track notification unit that transmits partial track data to each sensor node included in the node group indicated in the received node list;
a target tracker that generates partial track data;
a track integration unit that generates integrated track data obtained by integrating one or more partial track data;
an integrated track storage unit in which one or more integrated track data is stored;
a list storage unit that stores one or more node lists corresponding to the one or more integrated track data;
If the generated partial track data is not correlated with any of the one or more integrated track data, the list acquisition unit transmits the generated partial track data to the master node;
If the generated partial track data is correlated with any of the one or more integrated track data, the partial track notification unit correlates with the generated partial track data among the one or more node lists. Refer to the node list corresponding to the integrated track data, and send the generated partial track data to each sensor node included in the node group indicated in the referenced node list.
Track integrator. each node list includes an integrated track identifier that identifies corresponding integrated track data;
When integrated track data correlated with generated partial track data is stored in the integrated track storage unit, the target tracking unit adds an integrated track identifier for identifying the integrated track data to the generated partial track data. including
The list acquisition unit transmits the generated partial track data to the master node when the generated partial track data does not include an integrated track identifier,
2. When the generated partial track data includes the integrated track identifier, the partial track notification unit refers to a node list including the same integrated track identifier as the integrated track identifier included in the generated partial track data. A track integrator as described in . The track integration device is provided in a sensor node different from the one or more sensor nodes,
The master node generates a node list including integrated track identifiers, transmits the generated node list to each sensor node included in the node group indicated in the generated node list,
The list acquisition unit
receiving the generated node list when the generated node list is transmitted to the sensor node equipped with the track integrator;
storing the received node list in the list storage unit if no node list containing the same integrated track identifier as the integrated track identifier included in the received node list is stored in the list storage unit;
If a node list containing the same integrated track identifier as the integrated track identifier included in the received node list is stored in the list storage unit, the node list stored in the list storage unit is transferred to the received node list. The track integrator according to claim 2 , wherein updating is performed using a list. The list acquisition unit
if a node list containing an integrated track identifier that is the same as the integrated track identifier included in the received node list is stored in the list storage unit, referring to the node list stored in the list storage unit;
updating the referenced node list with the received node list if the node group indicated in the referenced node list includes the sensor node including the track integrator;
4. The track integrator according to claim 3 , wherein the referenced node list is deleted when the node group indicated in the referenced node list does not include the sensor node including the track integrator. a partial track reception unit that receives one or more partial track data, each representing a portion of the track, from a plurality of sensor nodes;
a group selector that selects a node group based on the received one or more partial track data;
a group specifying unit that transmits a node list indicating the selected node group to each sensor node included in the selected node group;
an integrated track storage unit that stores one or more integrated track data obtained by integrating one or more partial track data;
a list storage unit that stores one or more node lists corresponding to the one or more integrated track data;
When partial track data is received from any of the sensor nodes, the group selection unit selects integrated track data correlated with the received partial track data from the one or more integrated track data, and selects the selected integrated track data. selecting a node group based on the integrated track data, selecting a node list corresponding to the selected integrated track data from the one or more node lists, and transferring the selected node list to the selected node group; update based on
Track integrated management device. each node list includes an integrated track identifier that identifies corresponding integrated track data;
The integrated track management device according to claim 5 , wherein the group selection unit selects a node list including an integrated track identifier that is the same as an integrated track identifier that identifies selected integrated track data. Each sensor node has a sensor,
The group selection unit
If at least part of the integrated track indicated by the integrated track data correlated with the received partial track data is included in the coverage area of the sensor provided in the sensor node, the sensor node is included in the node group to be selected, and A request not to include the sensor node in the node group to be selected when the coverage area of the sensor provided in the sensor node does not include even a part of the integrated track indicated by the integrated track data correlated with the received partial track data. The track integrated management device according to claim 5 or claim 6 . The track integrated management device,
a track integration unit that updates integrated track data correlated with the received partial track data based on the received partial track data;
The integrated track management device according to any one of claims 5 to 7 , wherein the group selection unit selects a node group based on updated integrated track data. If integrated track data correlated with the received partial track data is not stored in the integrated track storage unit, the track integration unit generates integrated track data based on the received partial track data, and generates the integrated track data. storing the integrated track data in the integrated track storage unit;
8. The group selection unit selects a node group based on the generated integrated track data, generates a node list indicating the selected node group, and stores the generated node list in the list storage unit. Track integrated management device described in. The group selection unit
When integrated track data is generated, a predicted track is calculated based on the generated integrated track data, and if at least a part of the calculated predicted track is included in the coverage area of the sensor provided in the sensor node, it is selected. 10. when the sensor node is included in the node group to be selected and the coverage area of the sensor provided in the sensor node does not include a part of the calculated predicted route, the sensor node is not included in the node group to be selected. Track integrated management device described in. The track integrated management device,
Receiving a change request for a node group indicated in a node list, changing the node group indicated in the node list based on the accepted change request, and modifying each sensor node included in the node group indicated in the node list after the change. 11. The track integrated management device according to any one of claims 5 to 10 , further comprising a group changing unit that transmits the node list after change to. A track integration program that communicates with a master node and one or more sensor nodes,
the master node is a node that selects a group of nodes based on one or more partial track data, each representing a portion of the track;
Each sensor node is a node that generates integrated track data obtained by integrating one or more partial track data,
The track integration program includes:
a list acquisition process of transmitting partial track data to the master node and receiving a node list indicating node groups from the master node;
partial track notification processing for transmitting partial track data to each sensor node included in the node group indicated in the received node list;
a target tracking process that generates partial track data;
a track integration process for generating integrated track data obtained by integrating one or more partial track data;
on the computer, and
If the generated partial track data is uncorrelated with any of the one or more integrated track data, the list acquisition process transmits the generated partial track data to the master node;
If the generated partial track data is correlated with any of the one or more integrated track data, the partial track notification process includes: Refers to the node list corresponding to the integrated track data correlated with the generated partial track data, and transmits the generated partial track data to each sensor node included in the node group indicated in the referenced node list.
Track integration program. partial track reception processing for receiving one or more partial track data each indicating a part of the track from a plurality of sensor nodes;
a group selection process that selects a node group based on the one or more partial track data received;
a group designation process of transmitting a node list indicating the selected node group to each sensor node included in the selected node group;
A track integrated management program for causing a computer to execute
When partial track data is received from any sensor node, the group selection process selects the received partial track data from one or more integrated track data obtained by integrating one or more partial track data. Selecting correlated integrated track data, selecting a node group based on the selected integrated track data, and selecting the selected integrated track data from one or more node lists corresponding to the one or more integrated track data. select the node list corresponding to and update the selected node list based on the selected node group
Track integrated management program.

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