JP5744320B2 - Positioning tracking device - Google Patents

Description

  The present invention relates to a positioning tracking device that predicts the positioning of a target position and the track of a target.

For example, in a situation where the target aircraft is turning on a runway or taxiway at an airport, as shown in FIG. 25, a transponder (TRAN1) installed above the target or below the target is installed. A signal transmitted from the antenna of the existing transponder (TRAN2) is received by a plurality of receiving stations (REV1 to REV6) installed at the airport, and the time of arrival (TOA) that is the arrival time of the signal is obtained. To do.
Here, the transponder antenna is generally several tens of centimeters in length, width, and height.
Moreover, when an aircraft is a target, generally, the total length of the aircraft and the tail are several tens of meters in size. For this reason, the antenna of the transponder is sufficiently small compared to the target aircraft.

In this way, since the antenna of the transponder is sufficiently small compared to the aircraft, under the circumstance where the aircraft is turning, the tail of the aircraft shields the signal transmitted from the antenna of the transponder, and the receiving station transmits the signal. You may not be able to receive. In the example of FIG. 25, the receiving stations (REV5 and REV6) cannot receive signals.
In the example of FIG. 25, the building blocks the signal transmitted from the antenna of the transponder, so that the receiving station (REV4) cannot receive the signal.

If the target aircraft is moving on a runway or taxiway at the airport, the signal transmitted from the antenna of the transponder (TRAN2) installed below the target is in a situation where it is easily shielded. It seems that the signal transmitted from the antenna of the transponder (TRAN1) installed above the target functions and the receiving station receives the signal.
FIG. 25 shows a situation in which the target aircraft is turning on a runway or taxiway at the airport. When the target aircraft is in flight, as shown in FIG. There may be a situation where the signal transmitted from the antenna of the transponder is shielded and the receiving station cannot receive the signal.

FIG. 27 is a configuration diagram showing a positioning tracking device disclosed in Non-Patent Document 1 below.
In the example of FIG. 27, (N + 1) receiving stations # 0, # 1,..., #I,..., #N are transmitted from the antennas of the transponders installed in the target aircraft. A signal is received and TOA that is the arrival time of the signal is output.
Hereinafter, TOA output from the receiving station # 0 is expressed as TOA (0), and TOA output from the receiving station #i is expressed as TOA (i).

The TDOA calculation processing unit 101 calculates an arrival time difference (TDOA: Time Difference Of Arrival) that is a time difference between a TOA output from a reference receiving station and a TOA output from another receiving station.
For example, when the reference receiving station is receiving station # 0, TDOA (i) is calculated from TOA (0) output from receiving station # 0 and TOA (i) output from receiving station #i. .
TDOA (i) = TOA (i) -TOA (0)
However, i = 1, 2,..., N.

When the TDOA calculation processing unit 101 calculates TDOA (i), the positioning position calculation processing unit 102 calculates a target positioning position from the TDOA (i) by a method such as a least square method.
Here, it is assumed that a three-dimensional vector (x, y, z) related to the target position is calculated as the target positioning position, but a two-dimensional vector (x, y) related to the target position, time bias A four-dimensional vector (x, y, z, tb) relating to tb and position (x, y, z) can also be calculated.

When the positioning position calculation processing unit 102 calculates the target positioning position, the positioning position tracking processing unit 103 substitutes the target positioning position into the linear Kalman filter and performs the target tracking process, thereby performing the target track prediction value. And the wake smooth value is calculated.
Here, the target wake is composed of a state vector having dimensions such as the target position, velocity, and acceleration, and an error covariance matrix (matrix indicating an error between the wake prediction value and the positioning position).
When the positioning position tracking processing unit 103 calculates the target track predicted value and the track smooth value, the display processing unit 104 displays the target track predicted value and the track smooth value on a display or the like.

Here, assuming that the dimension number of the positioning position calculated by the positioning position calculation processing unit 102 is n, (n + 1) receiving stations need to receive signals transmitted from the transponder and output the TOA. There is.
For example, when positioning a two-dimensional position, n = 2 and three receiving stations need to output TOA.
Similarly, when positioning a three-dimensional position, n = 3 and four receiving stations need to output TOA.

For this reason, in the positioning position calculation processing unit 102, for example, when four receiving stations # 0 to # 3 are installed, a certain receiving station cannot receive a signal and does not output a TOA. A three-dimensional position cannot be measured.
Even if four receiving stations receive signals and output a TOA, if two of the receiving stations are close to each other, the TOA output from the two receiving stations has an amount of information. Since there is no difference, it is substantially equivalent to the case where three receiving stations receive signals and output TOA, and one receiving station cannot receive signals and does not output TOA. It will be the same as the situation. Under such circumstances, the three-dimensional position cannot be measured.
In addition, when a receiving station installed far away receives a signal, the received power of the signal is lowered, and the accuracy of TOA may be deteriorated. In such a case, since the estimation error does not fall within the specified error, it becomes the same as the situation where the receiving station cannot receive the signal and does not output the TOA, and the three-dimensional position cannot be measured.

Therefore, as shown in FIG. 25 and FIG. 26, for example, four receiving stations required for positioning a three-dimensional position output TOA by shielding the target aircraft's tail, aircraft, or building. If it is not, or if the receiving station that outputs the TOA is close, the three-dimensional position cannot be measured.
The positioning of a two-dimensional position is the same as the case of positioning a three-dimensional position, except that the number of necessary receiving stations is different.

As described above, when the positioning position calculation processing unit 102 calculates the target positioning position, the positioning position tracking processing unit 103 substitutes the target positioning position into the linear Kalman filter and performs target tracking processing. .
For this reason, the number of receiving stations that receive signals transmitted from the antenna of the transponder and output the TOA decreases, and the target position cannot be measured (signal shielding occurs). Situation), it is difficult to accurately calculate the target track.
Note that when the positioning position tracking processing unit 103 calculates the target track predicted value, the previously calculated track smooth value is used. Therefore, if the calculation accuracy of the track smooth value is degraded, the target position is currently determined Even if it is in a situation where the position of the vehicle can be measured (a situation where the shielding of the signal is eliminated), the calculation accuracy of the target track prediction value deteriorates.

Ueda, Miyazaki, Kakuhari, Nibo, Koga, "About multi-lateration for airport monitoring", Research Institute for Electronic Navigation, 11th June 2011.

  Since the conventional positioning tracking device is configured as described above, the number of receiving stations that receive signals transmitted from the antenna of the transponder and output the TOA is reduced, and the target position is measured. Once the target track accuracy has deteriorated, the target position can be measured (signal blocking is eliminated). However, there was a problem that the target track accuracy did not recover to the original track accuracy immediately.

  The present invention has been made to solve the above-described problems. Even when the target position cannot be measured, the target position can be determined immediately after the target position can be determined. An object of the present invention is to obtain a positioning tracking device capable of accurately calculating the wake of the vehicle.

  The positioning tracking device according to the present invention receives a signal transmitted from a target and outputs a signal arrival time, and arrival times that are time differences between arrival times output from the plurality of reception stations. An arrival time difference calculating means for calculating a difference; a position positioning means for determining a target position from the arrival time difference calculated by the arrival time difference calculating means; and a target position determined by the position positioning means for tracking processing. By substituting into the filter and performing the target tracking process, the target tracking means for calculating the target track prediction value and the track smoothing value, and the target track prediction value and the track smoothing value calculated by the target tracking means are obtained. Display means for displaying and signal shielding determining means for determining whether or not signal shielding has occurred between the target and a plurality of receiving stations are provided, and the filter reset means has signal shielding caused by the signal shielding determining means. If it is determined that, in which so as to reset the track by the filter for the tracking process.

  According to the present invention, the signal shielding determining means for determining whether or not signal shielding has occurred between the target and the plurality of receiving stations is provided, and the filter resetting means has the signal shielding caused by the signal shielding determining means. If it is determined that the track of the target is reset, the wake of the tracking process filter is reset. Immediately, the target track can be accurately calculated.

It is a block diagram which shows the positioning tracking apparatus by Embodiment 1 of this invention. (A) It is explanatory drawing which shows the tracking process result when not resetting a wake, and (b) The tracking process result when a wake is reset. It is a block diagram which shows the positioning tracking apparatus by Embodiment 2 of this invention. (A) It is explanatory drawing which shows the process image of the tracking process by the positioning position tracking process part 3, (b) The process image of the tracking process by the TDOA tracking process part 7. It is a block diagram which shows the positioning tracking apparatus by Embodiment 3 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 4 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 5 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 6 of this invention. It is explanatory drawing which shows the stationary object shielding determination process by the stationary object shielding determination process part. It is explanatory drawing which shows the moving object shielding determination process by the moving object shielding determination process part. 5 is a flowchart showing a comprehensive shielding determination process by a comprehensive shielding determination processing unit 13; It is explanatory drawing which shows the correspondence of TOA detection of an actual receiving station, shielding by a stationary object, shielding by a moving object, and shielding by turning. It is a block diagram which shows the positioning tracking apparatus by Embodiment 7 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 8 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 9 of this invention. It is explanatory drawing which shows how to obtain | require the prior reliability of a constant velocity linear model. It is a flowchart which shows the multiple motion model tracking process including the reliability calculation of each model. It is a block diagram which shows the positioning tracking apparatus by Embodiment 10 of this invention. It is explanatory drawing which shows the setting process of the model transition probability by the transition probability control process part. It is a block diagram which shows the positioning tracking apparatus by Embodiment 11 of this invention. It is explanatory drawing which shows a TDOA exercise | movement model integrated tracking process. It is a block diagram which shows the positioning tracking apparatus by Embodiment 12 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 13 of this invention. It is a block diagram which shows the positioning tracking apparatus by Embodiment 14 of this invention. It is explanatory drawing which shows a mode that the tail of the aircraft is shielding the signal transmitted from the antenna of the transponder under the situation where the target aircraft is turning on the airport runway or taxiway. It is explanatory drawing which shows a mode that the aircraft body is shielding the signal transmitted from the antenna of the transponder in the condition where the aircraft which is a target is flying. It is a block diagram which shows the positioning tracking apparatus currently disclosed by the nonpatent literature 1.

Hereinafter, in order to explain the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.
Embodiment 1 FIG.
1 is a block diagram showing a positioning tracking device according to Embodiment 1 of the present invention.
In FIG. 1, (N + 1) receiving stations # 0, # 1,..., #I,..., #N receive signals transmitted from transponder antennas installed in an aircraft (target). Then, TOA (Time Of Arrival) that is the arrival time of the signal is output.
Hereinafter, TOA output from the receiving station # 0 is expressed as TOA (0), and TOA output from the receiving station #i is expressed as TOA (i).

The TDOA calculation processing unit 1 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, or a one-chip microcomputer, and TOA output from a reference receiving station and TOA output from other receiving stations A process of calculating a time difference of arrival (TDOA) is performed. The TDOA calculation processing unit 1 constitutes arrival time difference calculation means.
For example, when the reference receiving station is receiving station # 0, TDOA (i) is calculated from TOA (0) output from receiving station # 0 and TOA (i) output from receiving station #i. .
TDOA (i) = TOA (i) -TOA (0)
However, i = 1, 2,..., N.

The positioning position calculation processing unit 2 is composed of, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and calculates a target positioning position from TDOA (i) calculated by the TDOA calculation processing unit 1. Perform the process. The positioning position calculation processing unit 2 constitutes a position positioning unit.
The positioning position tracking processing unit 3 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, or a one-chip microcomputer, and the target positioning position calculated by the positioning position calculation processing unit 2 is, for example, a linear Kalman filter (tracking). The target track prediction value and the track smoothing value are calculated by substituting in the processing filter) and performing the target tracking process. The positioning position tracking processing unit 3 constitutes target tracking means.
The display processing unit 4 includes, for example, a GPU (Graphics Processing Unit), and performs a process of displaying the target track prediction value and the track smoothing value calculated by the positioning position tracking processing unit 3 on the display. The display processing unit 4 constitutes display means.

The turning shield determination processing unit 5 is constituted by, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and the output status and positioning position of TOA (i) by (N + 1) receiving stations #i. In consideration of the positioning status of the position by the calculation processing unit 2, a process is performed to determine whether or not signal shielding accompanying the turning of the aircraft occurs between the target aircraft and the plurality of receiving stations. The turning shielding determination processing unit 5 constitutes a signal shielding determination unit.
The filter reset processing unit 6 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like, and it is determined by the turning shielding determination processing unit 5 that signal shielding has occurred as the aircraft turns. If it is, a process of outputting a filter control signal instructing resetting of the wake by the linear Kalman filter to the positioning position tracking processing unit 3 is performed. The filter reset processing unit 6 constitutes a filter reset unit.

In the example of FIG. 1, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the positioning position tracking processing unit 3, the display processing unit 4, and the turning shielding determination Although it is assumed that each of the processing unit 5 and the filter reset processing unit 6 is configured by dedicated hardware, all or a part of the positioning tracking device may be configured by a computer.
For example, when the part excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the positioning position tracking processing unit 3, the display processing unit 4, and the turning shielding determination process The program describing the processing contents of the unit 5 and the filter reset processing unit 6 may be stored in the memory of the computer, and the CPU of the computer may execute the program stored in the memory.

Next, the operation will be described.
(N + 1) receiving stations #i receive signals transmitted in time series from antennas of transponders installed in the target aircraft, and time-series TOA (i) that is the arrival time of the signals. Output to. However, i = 0, 1, 2,..., N.
In the first embodiment, for convenience of explanation, it is assumed that the receiving station # 0 is a reference receiving station.

When the TDOA calculation processing unit 1 receives the TOA from the receiving station #i, the TOA (0) output from the receiving station # 0, which is the reference receiving station, and the TOA (i) output from other receiving stations Is calculated as TDOA (i).
TDOA (i) = TOA (i) -TOA (0)
However, i = 1, 2,..., N.

When the TDOA calculation processing unit 1 calculates TDOA (i), the positioning position calculation processing unit 2 calculates a target positioning position from the TDOA (i) by a method such as a least square method. Since the process of calculating the target positioning position from TDOA (i) is a known technique, detailed description thereof is omitted.
Here, it is assumed that a three-dimensional vector (x, y, z) related to the target position is calculated as the target positioning position, but a two-dimensional vector (x, y) related to the target position, time bias A four-dimensional vector (x, y, z, tb) relating to tb and position (x, y, z) can also be calculated.

When the positioning position calculation processing unit 2 calculates the target positioning position, the positioning position tracking processing unit 3 substitutes the target positioning position into, for example, a linear Kalman filter and performs target tracking processing, thereby performing target track prediction. Value and wake smooth value are calculated. Since the process itself for calculating the target track prediction value and the track smooth value using the linear Kalman filter is a known technique, detailed description thereof is omitted.
Here, the target wake is composed of a state vector having dimensions such as the target position, velocity, and acceleration, and an error covariance matrix (matrix indicating an error between the wake prediction value and the positioning position).
When the positioning position tracking processing unit 3 calculates the target track predicted value and the track smooth value, the display processing unit 4 displays the target track predicted value and the track smooth value on a display or the like.

Here, if the dimension number of the positioning position calculated by the positioning position calculation processing unit 2 is n, it is necessary that (n + 1) receiving stations receive the signals transmitted from the transponders and output the TOA. There is.
For example, when positioning a two-dimensional position, n = 2 and three receiving stations need to output TOA.
Similarly, when positioning a three-dimensional position, n = 3 and four receiving stations need to output TOA.

The turning shield determination processing unit 5 inputs TOA (i) output from (N + 1) receiving stations #i in time series, and inputs the positioning positions calculated by the positioning position calculation processing unit 2 in time series. To do.
The turning shield determination processing unit 5 manages the time series of TOA (i) for each receiving station, and satisfies the following condition (1) or condition (2), or the conditions (1) and (2) Is satisfied, it is determined that the signal shielding accompanying the turning of the aircraft occurs between the target aircraft and the plurality of receiving stations.

[Condition (1)]
In the sampling period of M ₁ times, the number T of samplings (a <b) where the number a of the receiving stations #i outputting TOA (i) is less than the number b necessary for calculating the positioning position is N _1. (T> N ₁ ) times. For example, b = 3 for two-dimensional positioning and b = 4 for three-dimensional positioning.
[Condition (2)]
The positioning position calculated by the positioning position calculation processing unit 2 is missing (even if the condition (1) is not satisfied, there is a variation in the TOA (i) output from the receiving station #i). Since the calculation of the position may be impossible, the case where the positioning position calculated by the positioning position calculation processing unit 2 is missing is also included in the condition).

The filter reset processing unit 6 outputs a filter control signal for instructing resetting of the wake by the linear Kalman filter to the positioning position tracking processing unit when it is determined by the turning shielding determination processing unit 5 that signal shielding accompanying the turning of the aircraft has occurred. 3 is output.
When the positioning position tracking processing unit 3 receives a filter control signal instructing resetting of the wake from the filter reset processing unit 6, the positioning position tracking processing unit 3 resets the track by the linear Kalman filter (deletes the track smoothing value calculated in the past) and calculates the previous time. The target tracking process is performed without using the wake smoothing value, and the target wake prediction value and the wake smoothing value are calculated.

Here, FIG. 2 is an explanatory view showing a result of tracking processing of a wake.
(A) shows the tracking process result when the wake is not reset, and (b) shows the tracking process result when the wake is reset.
In FIG. 2, ◯ indicates an observed value (target positioning position), a thick arrow indicates a wake, and a dotted line indicates a true target locus.
In the example of FIG. 2, as the target aircraft turns, the TOA is missing and the TDOA is missing. As a result, the positioning position is missing.
That is, when the TOA is missing, the TDOA cannot be calculated and the TDOA is missing. Further, when the TDOA is missing, the target positioning position cannot be calculated and the positioning position is missing. It is a causal relationship.

Even if the target positioning position is missing, if the target tracking process is performed using the past track before the turn, as shown in FIG. The overshoot of the wake that calculates a value that lies on the extension line in the direction indicated by 発 生 occurs, so the accuracy of the wake deteriorates. The influence of the overshoot of the wake is received even if the target positioning position can be obtained after the turn is completed, and thus it takes a long time to improve the deterioration of the wake accuracy.
On the other hand, if the positioning position of the target is missing, the past track before the turn is reset, and when the target tracking process is performed without using the past track, it is not affected by the overshoot of the track. Therefore, when the target positioning position is obtained after the turn is completed, the wake accuracy is immediately improved as shown in FIG.

  As apparent from the above, according to the first embodiment, considering the output status of TOA (i) by (N + 1) receiving stations #i and the positioning status of the position by the positioning position calculation processing unit 2, A turning shielding determination processing unit 5 is provided for determining whether or not signal shielding is caused by turning of the aircraft between the target aircraft and a plurality of receiving stations, and the filter reset processing unit 6 is a turning shielding determination processing unit. 5, when it is determined that signal shielding accompanying the turning of the aircraft has occurred, a filter control signal instructing resetting of the wake by the linear Kalman filter is output to the positioning position tracking processing unit 3. Even in a situation where the position cannot be determined, if the target position can be determined after that, there is an effect that the track of the target can be calculated accurately.

Embodiment 2. FIG.
3 is a block diagram showing a positioning tracking apparatus according to Embodiment 2 of the present invention. In the figure, the same reference numerals as those in FIG.
The TDOA tracking processing unit 7 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. By substituting in the (tracking process filter) and performing the target tracking process, the target track prediction value and the track smoothing value are calculated.
That is, the TDOA tracking processing unit 7 uses the TDOA (i) calculated by the TDOA calculation processing unit 1 as an observation value, calculates a track prediction value based on an extended Kalman filter related to the observation model, and calculates a track smooth value. Smoothing processing to be performed, and gate processing to determine whether or not the observation value falls within the gate centered on the prediction of the wake prediction value and the spread covariance matrix of the wake prediction value and the observation value To do. The TDOA tracking processing unit 7 constitutes target tracking means.

In the example of FIG. 3, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination process Although each of the unit 5 and the filter reset processing unit 6 is assumed to be configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 5 and the filter reset processing unit 6 may be stored in a computer memory so that the CPU of the computer executes the program stored in the memory.

  In the first embodiment, the positioning position tracking processing unit 3 performs target tracking processing based on a linear Kalman filter using the target positioning position calculated by the positioning position calculation processing unit 2 as an observation value. However, in the second embodiment, the TDOA tracking processing unit 7 uses the TDOA (i) calculated by the TDOA calculation processing unit 1 as an observation value and performs target tracking processing based on the extended Kalman filter related to the observation model. It differs in that it is implemented.

FIG. 4A shows a processing image of the tracking process by the positioning position tracking processing unit 3, and FIG. 4B is an explanatory diagram showing a processing image of the tracking process by the TDOA tracking processing unit 7.
In the example of FIG. 4, there is an observation situation in which there is a target wake at time t0, the observed value Ao1 at time t1, the observed value Bo2 at time t2, and the observed value Co3 at time t3.
Here, the observed value is a TDOA observed value or a distance difference observed value.
Note that there is a relationship “distance difference = light speed × TDOA” between the distance difference and TDOA. However, the speed of light is a constant value.

For example, when the positioning position calculation processing unit 2 calculates a two-dimensional positioning position, an attempt is made to calculate the positioning position using three observation values at the same time, but in the case of FIG. At t1, t2, and t3, since the observation value is one input, the positioning position cannot be calculated.
For this reason, in the case of Fig.4 (a), the positioning position tracking process part 3 cannot implement a tracking process in time t1, t2, t3.

In FIG. 4B, Bp1 and Cp1 are predicted observation values based on the track at the previous time t0, Ap2 and Cp2 are predicted observation values based on the track at the previous time t1, and Ap3 and Bp3 are predicted observations based on the track at the previous time t2. Represents a value.
For example, when the TDOA tracking processing unit 7 calculates a two-dimensional tracking position at time t1, it can be calculated using the predicted observation values Bp1, Cp1 and the observation value Ao1 based on the track at the previous time t0.
Similarly, at time t2, it is possible to calculate a two-dimensional tracking position using the predicted observation values Ap2, Cp2 and the observation value Bo2 based on the track at the previous time t1.
Similarly, at time t3, a two-dimensional tracking position can be calculated using the predicted observation values Ap3, Bp3 and the observation value Co3 based on the track at the previous time t2.

As is clear from the above, the tracking process performed by the TDOA tracking processing unit 7 can stably generate the wake by executing the target tracking process even in a situation where the number of TDOAs necessary for positioning is not available. .
FIG. 4 shows an example of calculating the two-dimensional tracking position, but the calculation of the three-dimensional tracking position is the same as the calculation of the two-dimensional tracking position except that the dimensions are different.

The filter reset processing unit 6 resets the wake by the extended Kalman filter when the turning shielding determination processing unit 5 determines that the signal shielding accompanying the turning of the aircraft has occurred in the same manner as in the first embodiment. Is output to the TDOA tracking processing unit 7.
When the TDOA tracking processing unit 7 receives a filter control signal instructing resetting of the wake from the filter reset processing unit 6, the TDOA tracking processing unit 7 resets the wake by the extended Kalman filter (deletes the wake smooth value calculated in the past) and calculates the previous time. The target tracking process is performed without using the track smoothing value, and the target track prediction value and the track smoothing value are calculated.

Embodiment 3 FIG.
FIG. 5 is a block diagram showing a positioning tracking device according to Embodiment 3 of the present invention. In the figure, the same reference numerals as those in FIG.
The turning shielding determination processing unit 8 is configured by, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. The TDOA calculation processing unit 1 calculates the TDOA (i) and the positioning position calculation processing unit 2. In consideration of the positioning situation of the position, a process is performed to determine whether or not signal shielding is occurring due to the turning of the aircraft between the target aircraft and a plurality of receiving stations. The turning shielding determination processing unit 8 constitutes a signal shielding determination unit.

The positioning tracking device of FIG. 5 shows an example in which the turning shield determination processing unit 8 is applied to the positioning tracking device of FIG. 3, but the turning shielding determination processing unit 8 is applied to the positioning tracking device of FIG. Also good.
In the example of FIG. 5, receiving stations # 0 to #N, which are components of the positioning tracking device, TDOA calculation processing unit 1, positioning position calculation processing unit 2, TDOA tracking processing unit 7, display processing unit 4, and turning shielding determination processing Although it is assumed that each of the unit 8 and the filter reset processing unit 6 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 8 and the filter reset processing unit 6 may be stored in a computer memory so that the CPU of the computer executes the program stored in the memory.

  In the first and second embodiments, the turning shielding determination processing unit 5 is a target when the condition (1) or the condition (2) is satisfied, or when the condition (1) and the condition (2) are satisfied. Although it has been shown that it is determined that the signal shielding accompanying the turning of the aircraft occurs between the aircraft and a plurality of receiving stations, the turning shielding determination processing unit 8 satisfies the following condition (3) or condition (4): If satisfied, or if condition (3) and condition (4) are satisfied, it is determined that signal shielding accompanying aircraft turning occurs between the target aircraft and multiple receiving stations. Also good.

[Condition (3)]
In the M ₂ sampling periods, the number T of samplings (c <d) where the calculated number c of TDOA (i) is less than the number d necessary for calculating the positioning position is N ₂ (T> N ₂ ). Over. For example, d = 3 for two-dimensional positioning and d = 4 for three-dimensional positioning.
[Condition (4)]
The positioning position calculated by the positioning position calculation processing unit 2 is missing (even if the condition (3) is not satisfied, because TDOA (i) calculated by the TDOA calculation processing unit 1 varies) Since the positioning position may not be calculated, the case where the positioning position calculated by the positioning position calculation processing unit 2 is missing is also included in the condition).

The filter reset processing unit 6 outputs, to the TDOA tracking processing unit 7, a filter control signal that instructs resetting of the wake when it is determined by the turning shielding determination processing unit 8 that signal shielding accompanying the turning of the aircraft has occurred. .
When the TDOA tracking processing unit 7 receives the filter control signal instructing resetting of the wake from the filter reset processing unit 6, the TDOA tracking processing unit 7 resets the wake (deletes the wake smooth value calculated in the past), and the wake calculated in the previous time. A target tracking process is performed without using a smooth value, and a target track prediction value and a track smooth value are calculated.

  In the case of the third embodiment, as in the first and second embodiments, even if the target position cannot be measured, if the target position can be determined after that, There is an effect that the track of the target can be accurately calculated.

Embodiment 4 FIG.
6 is a block diagram showing a positioning tracking device according to Embodiment 4 of the present invention. In the figure, the same reference numerals as those in FIG.
The turning shield determination processing unit 9 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like, considering the output status of TOA (i) by (N + 1) receiving stations #i. Thus, a process is performed to determine whether or not there is signal shielding accompanying the turning of the aircraft between the target aircraft and the plurality of receiving stations. The turning shielding determination processing unit 9 constitutes a signal shielding determination unit.

The positioning tracking device of FIG. 6 shows an example in which the turning shielding determination processing unit 9 is applied to the positioning tracking device of FIG. 3, but the turning shielding determination processing unit 9 is applied to the positioning tracking device of FIG. Also good.
In the example of FIG. 6, receiving stations # 0 to #N that are components of the positioning tracking device, TDOA calculation processing unit 1, positioning position calculation processing unit 2, TDOA tracking processing unit 7, display processing unit 4, and turning shielding determination processing Although it is assumed that each of the unit 9 and the filter reset processing unit 6 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 9 and the filter reset processing unit 6 may be stored in a computer memory so that the CPU of the computer executes the program stored in the memory.

In the first and second embodiments, the turning shielding determination processing unit 5 is a target when the condition (1) or the condition (2) is satisfied, or when the condition (1) and the condition (2) are satisfied. It has been shown that it is determined that the signal shielding accompanying the turning of the aircraft is occurring between the aircraft and a plurality of receiving stations. The turning shielding determination processing unit 9 determines whether or not the condition (2) is satisfied. If the condition (1) is satisfied without making a determination, it may be determined that signal shielding is occurring between the target aircraft and a plurality of receiving stations as the aircraft turns.
In this case, even if the condition (2) is satisfied, since it is not determined that signal shielding has occurred, the determination accuracy is slightly reduced, but the effect of reducing the processing load of the determination process is obtained.

Embodiment 5 FIG.
7 is a block diagram showing a positioning tracking apparatus according to Embodiment 5 of the present invention. In the figure, the same reference numerals as those in FIG.
The turning shield determination processing unit 10 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like, and takes into account the calculation status of TDOA (i) by the TDOA calculation processing unit 1 and is a target. Processing is performed to determine whether or not signal shielding occurs due to the turning of the aircraft between a certain aircraft and a plurality of receiving stations. The turning shielding determination processing unit 10 constitutes a signal shielding determination unit.

The positioning tracking device of FIG. 7 shows an example in which the turning shielding determination processing unit 10 is applied to the positioning tracking device of FIG. 3. However, the turning tracking determination processing unit 10 is applied to the positioning tracking device of FIG. Also good.
In the example of FIG. 7, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination process Although it is assumed that each of the unit 10 and the filter reset processing unit 6 is configured by dedicated hardware, all or a part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 10 and the filter reset processing unit 6 may be stored in a computer memory so that the CPU of the computer executes the program stored in the memory.

In the third embodiment, when the turning shielding determination processing unit 8 satisfies the condition (3) or the condition (4), or when the condition (3) and the condition (4) are satisfied, the target aircraft Although it has been shown that it is determined that signal shielding is occurring between a plurality of receiving stations as the aircraft turns, the turning shielding determination processing unit 9 determines whether or not the condition (4) is satisfied. Instead, when the condition (3) is satisfied, it may be determined that signal shielding accompanying the turning of the aircraft is occurring between the target aircraft and the plurality of receiving stations.
In this case, even if the condition (4) is satisfied, since it is not determined that signal shielding has occurred, the determination accuracy is slightly reduced, but the effect of reducing the processing load of the determination process is obtained.

Embodiment 6 FIG.
8 is a block diagram showing a positioning tracking apparatus according to Embodiment 6 of the present invention. In the figure, the same reference numerals as those in FIG.
The stationary object shielding determination processing unit 11 is configured by, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. A process of determining whether or not a predetermined stationary object enters between i is performed.
The moving object shielding determination processing unit 12 includes, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. A process of determining whether or not a predetermined moving object enters between i is performed.
The stationary object shielding determination processing unit 11 and the moving object shielding determination processing unit 12 constitute position determination means.

  The comprehensive shielding determination processing unit 13 is configured by, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like, and it is determined by the turning shielding determination processing unit 5 that signal shielding has occurred. The wake prediction value is not determined to be a position where a stationary object enters by the stationary object shielding determination processing unit 11, and the wake prediction value is a position where the moving object enters by the moving object shielding determination processing unit 12. If it is not determined, a process of outputting a filter control signal instructing resetting of the wake by the extended Kalman filter to the TDOA tracking processing unit 7 is performed. The comprehensive shielding determination processing unit 13 constitutes a filter reset unit.

The positioning tracking device of FIG. 8 shows an example in which the stationary object shielding determination processing unit 11, the moving object shielding determination processing unit 12, and the comprehensive shielding determination processing unit 13 are applied to the positioning tracking device of FIG. The object shielding determination processing unit 11, the moving object shielding determination processing unit 12, and the comprehensive shielding determination processing unit 13 may be applied to the positioning tracking device of FIG.
In the example of FIG. 8, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination process It is assumed that each of the unit 5, the stationary object shielding determination processing unit 11, the moving object shielding determination processing unit 12, and the comprehensive shielding determination processing unit 13 is configured by dedicated hardware, but the entire positioning tracking device Or one part may be comprised with the computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 5. The program describing the processing contents of the stationary object shielding determination processing unit 11, the moving object shielding determination processing unit 12, and the comprehensive shielding determination processing unit 13 is stored in the memory of the computer, and the CPU of the computer stores the program in the memory. What is necessary is just to run the program currently carried out.

Next, the operation will be described.
Since it is the same as the first to fifth embodiments except that the stationary object shielding determination processing unit 11, the moving object shielding determination processing unit 12, and the comprehensive shielding determination processing unit 13 are mounted, mainly the stationary object shielding. Processing contents of the determination processing unit 11, the moving object shielding determination processing unit 12, and the comprehensive shielding determination processing unit 13 will be described.

When the TDOA tracking processing unit 7 calculates the track prediction value, the stationary object shielding determination processing unit 11 determines whether the track prediction value is a position where a predetermined stationary object enters between the target and the receiving station #i. judge.
Here, FIG. 9 is an explanatory diagram showing a stationary object shielding determination process by the stationary object shielding determination processing unit 11. Hereinafter, the stationary object shielding determination process will be specifically described with reference to FIG.

For example, when the target airplane travels on a runway of an airport as shown in FIG. 9, a stationary object such as a building may enter between the aircraft and the receiving station.
In such a case, the signal transmitted from the antenna of the transponder installed in the aircraft is shielded by the stationary object, and the receiving station cannot receive the signal.
However, the position where the receiver is installed and the position where the stationary object is installed are already known. It is possible to determine whether a signal transmitted from the antenna of the transponder is shielded by a stationary object.

Therefore, as shown in FIG. 9, the stationary object shielding determination processing unit 11 specifies the stationary object shielding range determined from the installation position of the known receiving station and the known stationary object in advance, and performs the TDOA tracking process. It is determined whether the wake prediction value calculated by the unit 7 is within the stationary object shielding range.
As a method for determining the stationary object shielding range, for example, a range in which the receiving station cannot receive radio waves is investigated in advance, and the range may be set as the stationary object shielding range, as shown in FIG. Alternatively, the size parameter of the stationary object may be specified, and the stationary object shielding range may be determined based on the size parameter.
The size parameter of the stationary object position, for example, when the stationary object is composed of one or more structures, specifies the spatial shape of each structure consisting of length, width and height, and combines the spatial shape of each structure, It may be determined comprehensively.
In FIG. 9, buildings in airports are stationary objects, but terrain and mountains may be stationary objects.

When the TDOA tracking processing unit 7 calculates the track prediction value, the moving object shielding determination processing unit 12 determines whether the track prediction value is a position where a predetermined moving object enters between the target and the receiving station #i. judge.
Here, FIG. 10 is an explanatory diagram showing the moving object shielding determination process by the moving object shielding determination processing unit 12. Hereinafter, the moving object shielding determination process will be specifically described with reference to FIG.

For example, when the target airplane travels on a runway of an airport as shown in FIG. 10, moving objects such as other airplanes may enter between the target aircraft and the receiving station.
In such a case, the signal transmitted from the antenna of the transponder installed in the target aircraft is shielded by the moving object, and the receiving station cannot receive the signal.
However, since the position where the receiver is installed is known, if the position of the moving object is known and the position of the target aircraft is known, it is currently installed on the aircraft. It can be determined whether a signal transmitted from the antenna of the transponder is shielded by a moving object.

Therefore, the moving object shielding determination processing unit 12 grasps the position of the moving object (for example, acquires a signal from an ADS-B or a GPS sensor mounted on the moving object to grasp the position of the moving object. ), A moving object shielding range determined from the position of the moving object and a known installation position of the receiving station is specified, and whether or not the predicted wake calculated by the TDOA tracking processing unit 7 is within the moving object shielding range. Determine whether.
In addition, when the position of a moving object cannot be grasped | ascertained from signals, such as ADS-B and a GPS sensor mounted in a moving object, a position may be grasped | ascertained by the tracking process similar to the said target, The position of the moving object may be grasped by a radar or the like.
In FIG. 10, other aircraft in the airport are used as moving objects. For example, clouds, rain, fog, etc. that are assumed to interfere with radio waves may be used as moving objects. The positions of clouds, rain and fog can be grasped by a dedicated sensor for observing the positions of clouds, rain and fog.

When it is determined that the signal shielding has occurred by the turning shielding determination processing unit 5, the total shielding determination processing unit 13 has a wake prediction value that is a position where a stationary object enters by the stationary object shielding determination processing unit 11. If it is not determined and the wake prediction value is not determined by the moving object shielding determination processing unit 12 to be a position where the moving object enters, a filter control signal for instructing resetting of the wake by the extended Kalman filter is recorded as TDOA tracking. Output to the processing unit 7.
Here, FIG. 11 is a flowchart showing the comprehensive shielding determination process by the comprehensive shielding determination processing unit 13.
FIG. 12 is an explanatory diagram showing a correspondence relationship between the actual TOA detection of the receiving station, shielding by a stationary object, shielding by a moving object, and shielding by turning.

Hereinafter, the comprehensive shielding determination process will be specifically described with reference to FIGS. 11 and 12.
In FIG. 12, when TOA detection is present, it is indicated by ○, and when TOA detection is not indicated by ×, if any one of shielding by a stationary object, shielding by a moving object, and shielding by turning, there is no TOA detection. Thus, only when there is no shielding, TOA detection is possible.
When the target tracking process is performed using the past wake before the turn when the shielding is caused by the turn, the wake overshoot occurs as described above, so the accuracy of the wake deteriorates.
However, when the shielding by a stationary object or the shielding by a moving object occurs, the target is not turning, so even if the target tracking process is performed using the past wake, The possibility of overshooting is considered low.
Therefore, in the sixth embodiment, the reason why the receiver cannot receive the signal is only when the turning is shielded, and the past wake is reset, and the reason why the receiver cannot receive the signal is the shielding or movement by the stationary object. In the case of blocking by an object, the target tracking process is continuously performed using the past wake without resetting the past wake.

That is, if the determination result of the stationary object shielding determination processing unit 11 indicates that “there is shielding by a stationary object”, the comprehensive shielding determination processing unit 13 continues the wake without resetting the past wake. Is notified to the TDOA tracking processing unit 7 (steps ST1 and ST2).
When the determination result of the stationary object shielding determination processing unit 11 indicates that “there is no shielding by a stationary object”, the comprehensive shielding determination processing unit 13 indicates that the determination result of the moving object shielding determination processing unit 12 is “moving object”. If it is indicated that “there is shielding by”, the TDOA tracking processing unit 7 is notified that the wake is continued without resetting the previous wake (steps ST3 and ST4).

When the determination result of the moving object shielding determination processing unit 12 indicates that “there is no shielding by the moving object”, the comprehensive shielding determination processing unit 13 indicates that the determination result of the turning shielding determination processing unit 5 is “no shielding by turning”. ”Is notified to the TDOA tracking processing unit 7 that the wake is continued without resetting the previous wake (steps ST5 and ST6).
On the other hand, if the determination result of the turning shielding determination processing unit 5 indicates that “there is shielding by turning”, a filter control signal instructing resetting of the wake is output to the TDOA tracking processing unit 7.

  As is apparent from the above, according to the sixth embodiment, whether or not the predicted wake calculated by the TDOA tracking processing unit 7 is a position where a predetermined stationary object enters between the target and the receiving station #i. It is determined whether or not the track prediction value calculated by the stationary object shielding determination processing unit 11 and the TDOA tracking processing unit 7 is a position where a predetermined moving object enters between the target and the receiving station #i. A moving object shielding determination processing unit 12, and when the comprehensive shielding determination processing unit 13 determines that signal shielding has occurred by the turning shielding determination processing unit 5, the stationary object shielding determination processing unit 11 tracks the wake. If the predicted value is not determined to be a position where a stationary object enters, and the predicted wake value is not determined to be a position where a moving object enters by the moving object shielding determination processing unit 12, the wake is reset. Instruct to fill Since the control signal is configured to be output to the TDOA tracking processing unit 7, even if the target tracking process is performed using the past wake, it is considered that the possibility that the shoot overshoot is low is low. In the case of occlusion by occlusion or occlusion by a moving object, the target tracking process can be continued without resetting the wake, and the effect of improving the target tracking accuracy is achieved.

Embodiment 7 FIG.
FIG. 13 is a block diagram showing a positioning tracking apparatus according to Embodiment 7 of the present invention. In the figure, the same reference numerals as those in FIG.
The motion model control processing unit 14 is configured by, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like, and the target in the TDOA tracking processing unit 7 is determined according to the determination result of the turning shielding determination processing unit 5. A process for controlling the tracking process is executed.
In other words, the motion model control processing unit 14 determines the target track prediction value when the turn shielding determination processing unit 5 determines that signal shielding has occurred, rather than when it is determined that signal shielding has not occurred. Processing for instructing the TDOA tracking processing unit 7 to increase the driving noise covariance matrix used for the calculation is performed. The motion model control processing unit 14 constitutes tracking processing control means.

The positioning tracking device of FIG. 13 shows an example in which the motion model control processing unit 14 is applied to the positioning tracking device of FIG. 3, but the motion model control processing unit 14 is applied to the positioning tracking device of FIG. Also good.
In the example of FIG. 13, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination process Although it is assumed that each of the unit 5 and the motion model control processing unit 14 is configured by dedicated hardware, all or a part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 5 and the motion model control processing unit 14 may be stored in a computer memory so that the CPU of the computer executes the program stored in the memory.

Next, the operation will be described.
Since the movement model control processing unit 14 is provided in place of the filter reset processing unit 6, it is the same as in the first to sixth embodiments, and thus the processing content of the movement model control processing unit 14 will be mainly described. .

First, the relational expression between the error covariance matrix and the drive noise covariance matrix used when the TDOA tracking processing unit 7 calculates the target track prediction value is as shown in the following expression (1).

The motion model control processing unit 14 determines that when the shielding shielding determination processing unit 5 determines that signal shielding has occurred, the driving model covariance matrix Q ( Instructs the TDOA tracking processing unit 7 to increase k-1).
When receiving an instruction from the motion model control processing unit 14 to increase the driving noise covariance matrix Q (k−1), the TDOA tracking processing unit 7 increases the driving noise covariance matrix Q (k−1). The target track prediction value is calculated, but by increasing the drive noise covariance matrix Q (k-1), the observed value and the predicted value from which the track is calculated in the target tracking process are The gain of the ratio used by weighting is increased. That is, when the driving noise covariance matrix Q (k−1) is increased, the weight of the observation value is increased.
As a result, even if the target tracking process is performed using the past wake before the turn, the wake overshoot accompanying the turn of the target is reduced.

  As apparent from the above, according to the seventh embodiment, when the motion model control processing unit 14 determines that the signal shielding has occurred by the turning shielding determination processing unit 5, the signal shielding has occurred. Since it is configured to instruct the TDOA tracking processing unit 7 to increase the driving noise covariance matrix Q (k−1) used when calculating the target track prediction value than when it is determined that Even if the target position cannot be measured, if the target position can be determined after that, the target track can be accurately calculated immediately.

Embodiment 8 FIG.
FIG. 14 is a block diagram showing a positioning tracking apparatus according to Embodiment 8 of the present invention. In the figure, the same reference numerals as those in FIG.
The motion model control processing unit 15 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, or a one-chip microcomputer, and when it is determined by the turning shielding determination processing unit 5 that signal shielding has occurred, A process for controlling the target tracking process in the TDOA tracking processing unit 7 is performed according to the determination result of the turning shielding determination processing unit 5.
In other words, the motion model control processing unit 15 determines that the target wake prediction value is calculated in consideration of the target acceleration when the turning shield determination processing unit 5 determines that signal shielding has occurred. A process instructing the unit 7 is performed. The motion model control processing unit 15 constitutes tracking processing control means.

The positioning tracking device of FIG. 14 shows an example in which the motion model control processing unit 15 is applied to the positioning tracking device of FIG. 3, but the motion model control processing unit 15 is applied to the positioning tracking device of FIG. Also good.
In the example of FIG. 14, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination process Although it is assumed that each of the unit 5 and the motion model control processing unit 15 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA tracking processing unit 7, the display processing unit 4, and the turning shielding determination processing unit 5 and the motion model control processing unit 15 may be stored in a computer memory so that the CPU of the computer executes the program stored in the memory.

Next, the operation will be described.
Since the motion model control processing unit 15 is provided in place of the filter reset processing unit 6, it is the same as in the first to sixth embodiments, and therefore the processing content of the motion model control processing unit 15 will be mainly described. .

The TDOA tracking processing unit 7 calculates a target track prediction value by the following equation (2).

The motion model control processing unit 15 indicates that the target wake prediction value is calculated by the above equation (2) when the turning shielding determination processing unit 5 determines that signal shielding has not occurred. 7, when it is determined by the turn shielding determination processing unit 5 that signal shielding has occurred, the TDOA tracking processing unit 7 is informed that the target track prediction value is calculated by the following equation (3). Instruct.

  Thereby, when it is determined by the turn shielding determination processing unit 5 that signal shielding has occurred, the TDOA tracking processing unit 7 calculates the target track prediction value in consideration of the target acceleration. It becomes possible to improve the followability to the turning target.

Embodiment 9 FIG.
15 is a block diagram showing a positioning tracking apparatus according to Embodiment 9 of the present invention. In the figure, the same reference numerals as those in FIG.
The TDOA multiple motion model tracking processing unit 16 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted or a one-chip microcomputer, and the TDOA (i) calculated by the TDOA calculation processing unit 1 is used as various motions. Combined with extended Kalman filters (filters for tracking processing) related to models (for example, constant-velocity straight-running models and turning models), target tracking processing (multi-motion model tracking processing) is performed, and target track prediction values and track A process of calculating a smooth value is performed. The TDOA multiple motion model tracking processing unit 16 constitutes target tracking means.

The transition probability control processing unit 17 is constituted by, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like, and a TDOA multiple motion model tracking processing unit according to the determination result of the turning shielding determination processing unit 5 The process which controls the target tracking process in 16 is implemented.
That is, the transition probability control processing unit 17 performs a process of setting the model transition probability of the multiple motion model tracking process according to the determination result of the turning shield determination processing unit 5. The transition probability control processing unit 17 constitutes tracking processing control means.

The positioning tracking device of FIG. 15 shows an example in which the TDOA multiple motion model tracking processing unit 16 and the transition probability control processing unit 17 are applied to the positioning tracking device of FIG. The transition probability control processing unit 17 may be applied to the positioning tracking device of FIG.
In the example of FIG. 15, receiving stations # 0 to #N, which are components of the positioning tracking device, TDOA calculation processing unit 1, positioning position calculation processing unit 2, TDOA multiple motion model tracking processing unit 16, display processing unit 4, turning Although it is assumed that each of the shielding determination processing unit 5 and the transition probability control processing unit 17 is configured by dedicated hardware, all or a part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA multiple motion model tracking processing unit 16, the display processing unit 4, the turning shield A program describing the processing contents of the determination processing unit 5 and the transition probability control processing unit 17 may be stored in the memory of a computer, and the CPU of the computer may execute the program stored in the memory.

Next, the operation will be described.
Since this embodiment is the same as Embodiments 1 to 6 except that a TDOA multiple motion model tracking processing unit 16 and a transition probability control processing unit 17 are provided instead of the filter reset processing unit 6 and the TDOA tracking processing unit 7. The processing contents of the TDOA multiple motion model tracking processing unit 16 and the transition probability control processing unit 17 will be mainly described.

As the multiple motion model tracking processing in the TDOA multiple motion model tracking processing unit 16, for example, a constant velocity linear motion model, a constant acceleration motion model, a constant angular velocity motion model, a meandering motion model, an external force (for example, gravity, Coriolis force, lift force, It is possible to combine various types of motion models such as an air resistance force factor, and to determine the number of motion models in the combination.
In the following description, for the sake of convenience, the constant velocity linear motion model is referred to as a “straight-ahead model”, and the constant acceleration motion model, the constant angular velocity motion model, the meandering motion model, and the like that have a large driving noise representing the ambiguity of motion are referred to as the “swivel model”. Called.

  The transition probability control processing unit 17, when the turning shielding determination processing unit 5 determines that signal shielding has occurred, the TDOA multi-motion model tracking processing unit 16, from the constant speed straight model to the turning model. Set to increase the transition probability.

ただし、ｖ_k,bは時刻ｋの運動モデルｂの尤度、μ_k,b(-)は時刻ｋの運動モデルｂの事前信頼度である
また、Ｎは運動モデル数、ｂは等速直進モデル又は旋回モデルのいずれかの運動モデルを示す変数である。Hereinafter, the model transition probability used for the model reliability calculation will be described.
The posterior reliability of the motion model b at time k is defined as μ _{k, b (+)} .
The posterior reliability μ _{k, b (+)} of the motion model b at time k is calculated by the following equation (4).

Where v _{k, b} is the likelihood of the motion model b at the time k, μ _{k, b (−)} is the prior reliability of the motion model b at the time k, N is the number of motion models, and b is a constant speed straight line It is a variable indicating a motion model of either a model or a turning model.

  Here, for simplification of explanation, the motion model is narrowed down to two models, a constant velocity straight-ahead model and a turning model, but an acceleration motion model, a constant acceleration motion model, and the like may be included. Combinations of exercise models and the number of exercise models can be determined in advance as one or more.

Next, the mixing process of the constant speed straight model will be described.
In the mixing process, prior reliability and posterior reliability are used as follows.

Here, the reverse transition probability μ _{k, b |} a from the motion model a to the motion model b is calculated by the following equation (7).

Here, the prior reliability μ _{k + 1, a (−)} of the motion model b at time k + 1 is calculated by the following equation (8).

In the mixing of the constant-velocity linear model, the mixed smooth vector based on the constant-velocity linear model, the mixed smoothing error covariance matrix based on the constant-velocity linear model, and the smooth vector of the constant-velocity linear model according to the above equations (5) to (8) Then, the smoothing error covariance matrix of the constant-velocity linear model, the inverse transition probability from the constant-velocity linear model to the turning model, and the prior reliability of the constant-velocity linear model are calculated.
In the mixing of the turning models, the same processing is performed by the above formulas (5) to (8) by replacing the above-mentioned constant-velocity linear model with the turning model and the above-mentioned turning model with the constant-velocity linear motion model. Is called.

Here, the prior reliability of multiple models in vector format is called "preliminary reliability vector", and the transition probability in matrix format considering all the possibilities of model transition is called "model transition probability matrix ".
The prior reliability vector μ _{k, a (-)} when the number of models is 2 (constant speed straight model, turning model) is given by the following formula (9), and the model transition probability matrix P _ba is given by the following formula (10). Become. The sum of the elements in each row of the model transition probability matrix P _ba is 1.

FIG. 16 is an explanatory diagram showing how to obtain the prior reliability of the constant-velocity linear model.
As shown in FIG. 16, the prior reliability at the time k of the constant velocity straight model is obtained by multiplying the posterior reliability at the time k−1 by the transition probability π ₁₁ and the transition probability π ₂₁ in the posterior reliability of the turning model. Multiplication is performed and the sum of these multiplication results is obtained. The same idea applies when the number of models is 3 or more.
FIG. 17 is a flowchart showing the multiple motion model tracking process including the reliability calculation of each model.

  As described above, according to the ninth embodiment, when it is determined that the signal shielding has occurred by the turning shielding determination processing unit 5, the constant velocity straight-ahead model is used for the TDOA multiple motion model tracking processing unit 16. Since the configuration is such that the model transition probability from the to the turning model is increased, the followability to the turning target can be improved.

Embodiment 10 FIG.
18 is a block diagram showing a positioning tracking apparatus according to Embodiment 10 of the present invention. In the figure, the same reference numerals as those in FIG.
The transition probability control processing unit 18 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, or a one-chip microcomputer. The transition probability control processing unit 18 is similar to the transition probability control processing unit 17 of FIG. Depending on the judgment result, the model transition probability of the multiple motion model tracking process is set, but when changing the model transition probability of the multiple motion model tracking process, the model transition probability is changed by multiple sampling. Do it step by step. The transition probability control processing unit 18 constitutes tracking processing control means.

In the example of FIG. 18, receiving stations # 0 to #N, which are components of the positioning tracking device, TDOA calculation processing unit 1, positioning position calculation processing unit 2, TDOA multiple motion model tracking processing unit 16, display processing unit 4, turning Although it is assumed that each of the shielding determination processing unit 5 and the transition probability control processing unit 18 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer.
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA multiple motion model tracking processing unit 16, the display processing unit 4, the turning shield A program describing the processing contents of the determination processing unit 5 and the transition probability control processing unit 18 may be stored in the memory of a computer, and the CPU of the computer may execute the program stored in the memory.

  In the ninth embodiment, the transition probability control processing unit 17 sets the model transition probability of the multiple motion model tracking process according to the determination result of the turning shielding determination processing unit 5, but the transition probability control process The unit 18 may gradually increase the model transition probability of the multiple motion model tracking process by a plurality of samplings by an increase method determined in advance.

FIG. 19 is an explanatory diagram showing a model transition probability setting process performed by the transition probability control processing unit 18.
For example, the transition probability control processing unit 18 does not change the model transition probability from the constant-velocity linear model to the turning model by one sampling, but changes the model transition probability by performing a plurality of samplings as shown in FIG. Do it step by step.
The method of changing the model transition probability may be linear or curvilinear.

  As is apparent from the above, according to the tenth embodiment, when changing the model transition probability of the multiple motion model tracking process, the model transition probability is changed stepwise by applying a plurality of samplings. Therefore, there is an effect that the followability from straight to turning is smooth.

Embodiment 11 FIG.
20 is a block diagram showing a positioning tracking apparatus according to Embodiment 11 of the present invention. In the figure, the same reference numerals as those in FIG.
The TDOA motion model integrated tracking processing unit 19 is composed of, for example, a semiconductor integrated circuit mounted with a CPU or a one-chip microcomputer, and substitutes TDOA (i) calculated by the TDOA calculation processing unit 1 for an extended Kalman filter. Then, the target track prediction value and the track smooth value are calculated by performing the target tracking process. At this time, the processing result obtained from the tracking filter of the straight-ahead model in the extended Kalman filter and the extended Kalman filter The motion model integrated tracking process that integrates the processing result obtained from the tracking filter of the turning model in is performed. The TDOA motion model integrated tracking processing unit 19 constitutes target tracking means.

The integrated weighting control processing unit 20 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. The process which controls the target tracking process in 19 is implemented.
That is, the integrated weighting control processing unit 20 integrates the processing result obtained from the tracking model tracking filter and the processing result obtained from the tracking model tracking filter according to the determination result of the turning shielding determination processing unit 5. A process for setting the weight is performed. The integrated weighting control processing unit 20 constitutes tracking processing control means.

The positioning tracking device of FIG. 20 shows an example in which the TDOA motion model integrated tracking processing unit 19 and the integrated weighting control processing unit 20 are applied to the positioning tracking device of FIG. 3, but the TDOA motion model integrated tracking processing unit 19 The integrated weighting control processing unit 20 may be applied to the positioning tracking device of FIG.
In the example of FIG. 20, receiving stations # 0 to #N, which are components of the positioning tracking device, TDOA calculation processing unit 1, positioning position calculation processing unit 2, TDOA motion model integrated tracking processing unit 19, display processing unit 4, turning Although it is assumed that each of the shielding determination processing unit 5 and the integrated weighting control processing unit 20 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer.
For example, when the portions other than the receiving stations # 0 to #N are configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA motion model integrated tracking processing unit 19, the display processing unit 4, the turning shield A program describing the processing contents of the determination processing unit 5 and the integrated weighting control processing unit 20 may be stored in the memory of a computer, and the CPU of the computer may execute the program stored in the memory.
FIG. 21 is an explanatory diagram showing the TDOA motion model integrated tracking process.

Next, the operation will be described.
Since it is the same as that of the said Embodiments 1-6 except the point which has provided the TDOA motion model integrated tracking process part 19 and the integrated weighting control process part 20 instead of the filter reset process part 6 and the TDOA tracking process part 7. The processing contents of the TDOA motion model integrated tracking processing unit 19 and the integrated weighting control processing unit 20 will be mainly described.

When the TDOA calculation processing unit 1 calculates TDOA (i), the TDOA motion model integrated tracking processing unit 19 uses the TDOA (i) to perform tracking processing based on the constant-velocity linear model, so that the constant-velocity linear model The smoothed state vector x ¹ (k | k) is calculated.
Further, the TDOA motion model integrated tracking processing unit 19 performs tracking processing based on the turning model using the TDOA (i), and calculates a state vector x ² (k | k) of the smooth value of the turning model. To do.

When the TDOA motion model integrated tracking processing unit 19 calculates the state vector x ¹ (k | k) of the smooth value of the constant-velocity straight model and the state vector x ² (k | k) of the smooth value of the turning model, the TDOA motion model integrated tracking processing unit 19 Using the model weight β ₁ and the turning model weight β ₂ , as shown in the following equation (11), the smoothed state vector x ¹ (k | k) of the constant velocity linear model and the turning model The smoothed state vector x ² (k | k) is weighted and added to calculate the integrated smoothed value state vector x _gt (k | k).

The integrated weighting control processing unit 20 sets the weight β _{1 of the} straight traveling model and the weight β _{2 of the} turning model according to the determination result of the turning shielding determination processing unit 5.
That is, if the determination result of the turning shielding determination processing unit 5 indicates that “there is no shielding by turning”, the integrated weight control processing unit 20 uses the weight β _{1 of the} straight model from the weight β _{2 of the} turning model. The TDOA motion model integrated tracking processing unit 19 is instructed to increase the size, but if the determination result of the turning shielding determination processing unit 5 indicates that “there is shielding by turning”, the turning model is determined from the weight β _{1 of the} straight traveling model. Is instructed to increase the weight β ₂ of the TDOA motion model integrated tracking processing unit 19.
Thus, when there is shielding due to turning, the weight β _{2 of the} turning model is made larger than the weight β _{1 of the} straight-ahead model, and the integrated smooth value state vector x _gt (k | k) is calculated.
In this way, by changing the weighting of the TDOA motion model integrated tracking process according to the result of turning shielding determination, an effect of improving the followability to the target can be obtained.

Embodiment 12 FIG.
22 is a block diagram showing a positioning tracking apparatus according to Embodiment 12 of the present invention. In the figure, the same reference numerals as those in FIG.
The TDOA multiple motion model horizontal / vertical tracking processing unit 21 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. The target track prediction value and the track smoothing value are calculated by substituting for the target tracking process, and at this time, the horizontal target tracking is performed by combining a plurality of horizontal motion models. The multi-motion model tracking process in the direction and the multi-motion model tracking process in the vertical direction to track the target by combining multiple motion models in the vertical direction, and the processing result of the horizontal multi-motion model tracking process and the vertical It integrates the processing result of the multi-motion model tracking process of the direction. The TDOA multiple motion model horizontal / vertical tracking processing unit 21 constitutes target tracking means.

The model control processing unit 22 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted or a one-chip microcomputer, and the TDOA multiple motion model horizontal / vertical tracking processing is performed according to the determination result of the turning shielding determination processing unit 5. The process which controls the target tracking process in the part 21 is implemented.
That is, the model control processing unit 22 considers the determination result of the turning shield determination processing unit 5 and the topography, and calculates the model transition probability of the horizontal multi-motion model tracking process and the model transition probability of the vertical multi-motion model tracking process. Perform the setting process. The model control processing unit 22 constitutes tracking processing control means.

The positioning tracking device of FIG. 22 shows an example in which the TDOA multi-motion model horizontal / vertical tracking processing unit 21 and the model control processing unit 22 are applied to the positioning tracking device of FIG. The processing unit 21 and the model control processing unit 22 may be applied to the positioning tracking device of FIG.
In the example of FIG. 22, the receiving stations # 0 to #N, which are components of the positioning tracking device, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA multiple motion model horizontal / vertical tracking processing unit 21, and the display processing unit 4 In addition, although it is assumed that each of the turning shielding determination processing unit 5 and the model control processing unit 22 is configured with dedicated hardware, all or part of the positioning tracking device may be configured with a computer. .
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA multiple motion model horizontal / vertical tracking processing unit 21, the display processing unit 4, A program describing the processing contents of the turning shielding determination processing unit 5 and the model control processing unit 22 may be stored in the memory of a computer, and the CPU of the computer may execute the program stored in the memory. .

Next, the operation will be described.
The present embodiment is the same as Embodiments 1 to 6 except that a TDOA multiple motion model horizontal / vertical tracking processing unit 21 and a model control processing unit 22 are provided instead of the filter reset processing unit 6 and the TDOA tracking processing unit 7. Therefore, the processing contents of the TDOA multiple motion model horizontal / vertical tracking processing unit 21 and the model control processing unit 22 will be mainly described.

The method of multi-motion model tracking processing in the TDOA multi-motion model horizontal / vertical tracking processing unit 21 is the same as the method of multi-motion model tracking processing in the TDOA multi-motion model tracking processing unit 16 of FIG. The model tracking process and the vertical multiple motion model tracking process are performed independently.
When the TDOA multi-motion model horizontal / vertical tracking processing unit 21 performs the multi-motion model tracking process in the horizontal direction and the multi-motion model tracking process in the vertical direction independently, the multi-motion model tracking process in the horizontal direction can be performed. The obtained wake prediction value and the wake prediction value obtained by performing the vertical multiple motion model tracking process are combined and output to the display processing unit 4.
The TDOA multi-motion model horizontal / vertical tracking processing unit 21 also obtains a wake smooth value obtained by performing horizontal multi-motion model tracking processing and a wake obtained by performing vertical multi-motion model tracking processing. Together with the smoothed value, it is output to the display processing unit 4.

The model control processing unit 22 sets the model transition probability of the multi-motion model tracking process in the horizontal direction and the model transition probability of the multi-motion model tracking process in the vertical direction in consideration of the determination result of the turning shielding determination processing unit 5 and the topography. To do.
In other words, if the determination result of the turning shielding determination processing unit 5 indicates that “there is shielding by turning”, the model control processing unit 22 combines the horizontal altitude with the smooth altitude calculated from the wake smooth value. Increase the transition probability from the constant-velocity straight model to the swing model in the motion model tracking process, increase the transition probability from the constant-velocity straight model to the swing model in the vertical multiple motion model tracking process, or the horizontal multiple motion model It is determined whether to increase both the transition probability from the constant speed straight model to the turning model in the tracking process and the transition probability from the constant speed straight model to the turning model in the vertical multiple motion model tracking process.

For example, when it is known in advance that the turning in the altitude direction is small according to the target altitude, the smooth altitude is less than the altitude threshold (threshold when the altitude direction is low) and the turning shielding is performed. If the determination result of the determination processing unit 5 indicates that “there is shielding due to turning”, the process of increasing the transition probability from the constant-velocity straight-ahead model to the turning model is performed only in the horizontal multi-motion model tracking process. .
In other words, based on the relationship between the terrain position (positions of airports, mountains, buildings, etc.) and wake smoothness values (smooth position, smooth altitude, etc.), it is estimated to some extent whether the target turns in the altitude direction or in the horizontal direction in advance. Therefore, a table showing the correspondence relationship between the topographic position, the transition probability of the multi-motion model tracking process in the horizontal direction, and the transition probability of the multi-motion model tracking process in the vertical direction is created in advance. The transition probability of the horizontal multi-motion model tracking process corresponding to the terrain position and the transition probability of the vertical multi-motion model tracking process corresponding to the terrain position are acquired from the table.
Then, the control signal for setting the transition probability of the horizontal multi-motion model tracking process and the transition probability of the multi-motion model tracking process in the vertical direction is output to the TDOA multi-motion model horizontal / vertical tracking processing unit 21.

As a result, the TDOA multi-motion model horizontal / vertical tracking processing unit 21 determines the transition probability of the horizontal multi-motion model tracking processing and the vertical multi-motion model tracking processing according to the control signal output from the model control processing unit 22. The horizontal multi-motion model tracking process and the vertical multi-motion model tracking process are performed independently.
In this way, the model transition probability of the horizontal multi-motion model tracking process and the model transition probability of the multi-motion model tracking process in the vertical direction are set in consideration of the determination result of the turning shielding determination processing unit 5 and the terrain. , The ability to follow the target can be improved.

Embodiment 13 FIG.
FIG. 23 is a block diagram showing a positioning tracking apparatus according to Embodiment 13 of the present invention. In the figure, the same reference numerals as those in FIG.
The TDOA multiple motion model horizontal / vertical tracking processing unit 23 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted or a one-chip microcomputer, and is similar to the TDOA multiple motion model horizontal / vertical tracking processing unit 21 shown in FIG. The horizontal multi-motion model tracking processing and the vertical multi-motion model tracking processing are performed independently, the horizontal multi-motion model tracking processing result and the vertical multi-motion model tracking processing result. However, in the case of the TDOA multi-motion model horizontal / vertical tracking processing unit 23, the motion models of the horizontal multi-motion model tracking processing are the straight model and the turning model, and the vertical multi-motion model tracking is performed. The motion model of processing is a plurality of straight-ahead models with a constant altitude. The TDOA multiple motion model horizontal / vertical tracking processing unit 23 constitutes target tracking means.

  The model control processing unit 24 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. Similar to the model control processing unit 22 in FIG. 22, the model control processing unit 24 performs horizontal multiple motion model tracking processing. The model transition probability and the model transition probability of the multiple motion model tracking process in the vertical direction are set. In the case of the model control processing unit 24, the determination result of the turning shielding determination processing unit 5 is “there is shielding by turning”. In order to maintain the model transition probability of the vertical multi-motion model tracking process by setting the model transition probability from the straight model to the turning model in the horizontal multi-motion model tracking process to be large. To. The model control processing unit 24 constitutes tracking processing control means.

The positioning tracking device of FIG. 23 shows an example in which the TDOA multiple motion model horizontal / vertical tracking processing unit 23 and the model control processing unit 24 are applied to the positioning tracking device of FIG. The processing unit 23 and the model control processing unit 24 may be applied to the positioning tracking device of FIG.
In the example of FIG. 23, receiving stations # 0 to #N, which are components of the positioning tracking device, a TDOA calculation processing unit 1, a positioning position calculation processing unit 2, a TDOA multiple motion model horizontal / vertical tracking processing unit 23, and a display processing unit 4 In addition, although it is assumed that each of the turning shielding determination processing unit 5 and the model control processing unit 24 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer. .
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA multiple motion model horizontal / vertical tracking processing unit 23, the display processing unit 4, A program describing the processing contents of the turning shielding determination processing unit 5 and the model control processing unit 24 may be stored in the memory of the computer, and the CPU of the computer may execute the program stored in the memory. .

  In the thirteenth embodiment, the TDOA multi-motion model horizontal / vertical tracking processing unit 23 handles a straight-ahead model and a turning model for the horizontal multi-motion model tracking processing motion model. As for the motion model of the model tracking process, it is assumed that a plurality of straight-ahead models having a constant altitude are handled.

If the determination result of the turning shielding determination processing unit 5 indicates that “there is shielding by turning”, the model control processing unit 24 is the model transition probability from the straight model to the turning model in the horizontal multi-motion model tracking process. Is set to be large so that the model transition probability of the multiple motion model tracking process in the vertical direction is maintained.
Thereby, in the TDOA multiple motion model horizontal / vertical tracking processing unit 23, if the determination result of the turning shielding determination processing unit 5 indicates “there is shielding by turning”, the horizontal multiple motion model tracking processing is The target tracking is performed by a multiple motion model in which the model transition probability from the straight model to the turning model is increased.
As a result, the ability to follow the target can be ensured. In addition, by using a vertical multiple motion model that uses a plurality of straight-ahead models having a constant altitude, the altitude tracking accuracy to the target is improved even in a situation where the altitude error is large due to multipath or the like.

Embodiment 14 FIG.
24 is a block diagram showing a positioning tracking apparatus according to Embodiment 14 of the present invention. In the figure, the same reference numerals as those in FIG.
The model control processing unit 25 is composed of, for example, a semiconductor integrated circuit on which a CPU is mounted, a one-chip microcomputer, or the like. Similar to the model control processing unit 22 of FIG. 22, the model control processing unit 25 performs horizontal multiple motion model tracking processing. The model transition probability and the model transition probability of the multiple motion model tracking process in the vertical direction are set. In the case of the model control processing unit 25, the motion model of the multiple motion model tracking process in the vertical direction is the ascending turning model and the descending model. If the turning model is provided, it is determined whether to use the ascending turning model and the descending turning model according to the target altitude. The model control processing unit 25 constitutes tracking processing control means.

24 shows an example in which the TDOA multi-motion model horizontal / vertical tracking processing unit 21 and the model control processing unit 25 are applied to the positioning tracking device of FIG. 3, but the TDOA multi-motion model horizontal / vertical tracking unit is shown. The processing unit 21 and the model control processing unit 25 may be applied to the positioning tracking device of FIG.
In the example of FIG. 23, receiving stations # 0 to #N, which are components of the positioning tracking device, a TDOA calculation processing unit 1, a positioning position calculation processing unit 2, a TDOA multiple motion model horizontal / vertical tracking processing unit 21, and a display processing unit 4 Although it is assumed that each of the turning shielding determination processing unit 5 and the model control processing unit 25 is configured by dedicated hardware, all or part of the positioning tracking device may be configured by a computer. .
For example, when the portion excluding the receiving stations # 0 to #N is configured by a computer, the TDOA calculation processing unit 1, the positioning position calculation processing unit 2, the TDOA multiple motion model horizontal / vertical tracking processing unit 21, the display processing unit 4, A program describing the processing contents of the turning shielding determination processing unit 5 and the model control processing unit 25 may be stored in a memory of a computer, and the CPU of the computer may execute the program stored in the memory. .

Next, the operation will be described.
Except for the point that the model control processing unit 25 is provided in place of the model control processing unit 22, the processing is the same as that of the above-described Embodiment 12, and therefore the processing content of the model control processing unit 25 will be mainly described.
In the fourteenth embodiment, it is assumed that the TDOA multi-motion model horizontal / vertical tracking processing unit 21 includes an ascending turning model and a descending turning model as motion models for the vertical multi-motion model tracking process.

When the TDOA multi-motion model horizontal / vertical tracking processing unit 21 uses an ascending turning model, a descending turning model, and a straight traveling model, for example, when the smooth altitude obtained from the wake smooth value is equal to or higher than a certain altitude, the descending turning model is used. For example, a table indicating a correspondence relationship between the smooth altitude and whether or not the ascending turning model and the descending turning model are used is prepared in advance.
For example, when the model control processing unit 25 obtains a smooth altitude from the wake smooth value, the model control processing unit 25 refers to a table created in advance and determines whether the motion model used at the smooth altitude is an ascending turning model or a descending turning model. It confirms whether it is a model, and outputs a control signal indicating a motion model to be used to the TDOA multiple motion model horizontal / vertical tracking processing unit 21.

If the control signal output from the model control processing unit 25 indicates that the ascending turning model is used, the TDOA multi-motion model horizontal / vertical tracking processing unit 21 uses a vertical multi-motion model tracking process as a motion model. Use the ascending turning model.
If the control signal output from the model control processing unit 25 indicates that the descending turning model is to be used, the descending turning model is used as the motion model of the vertical multiple motion model tracking process.
Thus, depending on the target altitude, for example, depending on the target altitude, it is possible to determine whether to use the ascending and descending swivel models as the motion model for the vertical multi-motion model tracking process. It is possible to exclude operations of ascending and descending turns that cannot be obtained.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  In the positioning tracking device according to the present invention, it is determined that the signal shielding is generated by the signal shielding determination means for determining whether the signal shielding is occurring between the target and the plurality of receiving stations, and the signal shielding determination means. Filter reset means for resetting the wake of the tracking processing filter, even if the target position cannot be determined, the target position can be determined immediately. Since the target track can be accurately calculated, it is suitable for use as a positioning tracking device for positioning the position of the aircraft and predicting the track of the aircraft.

  # 0 to #N Receiving station, 1 TDOA calculation processing section (arrival time difference calculation means), 2 positioning position calculation processing section (position positioning means), 3 positioning position tracking processing section (target tracking means), 4 display processing section ( Display means), 5 turning shielding judgment processing section (signal shielding judgment means), 6 filter reset processing section (filter reset means), 7 TDOA tracking processing section (target tracking means), 8, 9, 10 turning shielding judgment processing section ( Signal shielding determination means), 11 stationary object shielding determination processing section (position determination means), 12 moving object shielding determination processing section (position determination means), 13 comprehensive shielding determination processing section (filter reset means), 14, 15 motion model control Processing unit (tracking processing control means), 16 TDOA multiple motion model tracking processing unit (target tracking means), 17, 18 Transition probability control processing unit (tracking processing control means), 19 TDO Motion model integrated tracking processing unit (target tracking means), 20 Integrated weight control processing unit (tracking processing control means), 21, 23 TDOA multiple motion model horizontal / vertical tracking processing unit (target tracking means), 22, 24, 25 Model control Processing unit (tracking processing control means), 101 TDOA calculation processing unit, 102 positioning position calculation processing unit, 103 positioning position tracking processing unit, 104 display processing unit.

Claims (15)

A plurality of receiving stations that receive signals transmitted from the target and output the arrival times of the signals;
An arrival time difference calculating means for calculating an arrival time difference which is a time difference between arrival times output from the plurality of receiving stations;
Position positioning means for positioning the target position from the arrival time difference calculated by the arrival time difference calculation means;
By substituting the target position measured by the position positioning means or the arrival time difference calculated by the arrival time difference calculating means into a filter for tracking processing, and performing the target tracking processing, A target tracking means for calculating a wake prediction value and a wake smooth value;
Display means for displaying the target track prediction value and the track smooth value calculated by the target tracking means;
Signal shielding determination means for determining whether signal shielding occurs between the target and the plurality of receiving stations;
A positioning tracking device comprising: a filter resetting unit that resets a track by the tracking processing filter when it is determined by the signal blocking determination unit that signal blocking has occurred. The signal blocking determining means, taking into account the positioning status of position by the receiving state and the positioning means of the signal by the plurality of receiving stations, whether the signal blocking between the target and the plurality of receiving stations is occurring The positioning tracking device according to claim 1, wherein: The signal blocking determining means, taking into account the positioning status position by calculating situation and the positioning means of arrival time difference according to the arrival time difference calculating means, and the signal blocking between the target and the plurality of receiving stations is generated The positioning tracking device according to claim 1, wherein it is determined whether or not it exists. 2. The signal shielding determination means determines whether or not signal shielding occurs between a target and the plurality of receiving stations in consideration of reception status of signals by the plurality of receiving stations. The positioning tracking device described. The signal blocking determining means, and characterized in that in consideration of the calculation conditions of the arrival time difference according to the arrival time difference calculating means, determining whether the signal blocking between the target and the plurality of receiving stations is occurring The positioning tracking device according to claim 1. A position determination means for determining whether or not the track prediction value calculated by the target tracking means is a position where a predetermined stationary object or moving object enters between the target and the receiving station;
The filter reset means, a signal is determined shield is generated by the signal blocking determining means, and, unless it is determined that the track prediction value is the position of the stationary or moving object enters by the position determining means The positioning tracking device according to claim 1, wherein the track by the tracking processing filter is reset. A plurality of receiving stations that receive signals transmitted from the target and output the arrival times of the signals;
An arrival time difference calculating means for calculating an arrival time difference which is a time difference between arrival times output from the plurality of receiving stations;
Position positioning means for positioning the target position from the arrival time difference calculated by the arrival time difference calculation means;
By substituting the target position measured by the position positioning means or the arrival time difference calculated by the arrival time difference calculating means into a filter for tracking processing, and performing the target tracking processing, A target tracking means for calculating a wake prediction value and a wake smooth value;
Display means for displaying the target track prediction value and the track smooth value calculated by the target tracking means;
Signal shielding determination means for determining whether signal shielding occurs between the target and the plurality of receiving stations;
A positioning tracking device comprising tracking processing control means for controlling the target tracking processing by increasing the gain of the tracking processing filter in the target tracking means in accordance with the determination result of the signal shielding determination means. The tracking processing control means, if the signal shielded is determined to be generated by the signal blocking determining means, than if the signal shielded is determined not to have occurred, when calculating the wake prediction value of the target positioning tracking device according to claim 7, characterized in that instructs the target tracking means to the effect that increasing the driving noise covariance matrix used to. A plurality of receiving stations that receive signals transmitted from the target and output the arrival times of the signals;
An arrival time difference calculating means for calculating an arrival time difference that is a time difference between arrival times output from the plurality of receiving stations;
Position positioning means for positioning the target position from the arrival time difference calculated by the arrival time difference calculation means;
By substituting the target position measured by the position positioning means or the arrival time difference calculated by the arrival time difference calculating means into a filter for tracking processing, and performing the target tracking processing, A target tracking means for calculating a wake prediction value and a wake smooth value;
Display means for displaying the target track prediction value and the track smooth value calculated by the target tracking means;
Signal shielding determination means for determining whether signal shielding occurs between the target and the plurality of receiving stations;
If the signal blocking is determined to be generated by the signal blocking judging means, taking into account the acceleration of the target, and tracking processing control means to the effect of calculating the trajectory prediction value of the target instructs the target tracking means
Positioning tracking device equipped with . A plurality of receiving stations that receive signals transmitted from the target and output the arrival times of the signals;
An arrival time difference calculating means for calculating an arrival time difference that is a time difference between arrival times output from the plurality of receiving stations;
Position positioning means for positioning the target position from the arrival time difference calculated by the arrival time difference calculation means;
By substituting the target position measured by the position positioning means or the arrival time difference calculated by the arrival time difference calculating means into a filter for tracking processing, and performing the target tracking processing, A target tracking means for calculating a wake prediction value and a wake smooth value;
Display means for displaying the target track prediction value and the track smooth value calculated by the target tracking means;
Signal shielding determination means for determining whether signal shielding occurs between the target and the plurality of receiving stations;
Tracking process control means for controlling target tracking processing in the target tracking means according to the determination result of the signal shielding determination means,
The target tracking means performs a multiple motion model tracking process for tracking a target by combining various motion models.
The tracking processing control means in accordance with the determination result of the signal blocking determining means, measuring position tracking device you and sets the model transition probability of the multiple motion model tracking process. The tracking processing control means, to change the model transition probability of a multiple motion model tracking process, over a plurality of sampling positioning tracking of claim 10, wherein the performing stepwise change of the model transition probability apparatus. A plurality of receiving stations that receive signals transmitted from the target and output the arrival times of the signals;
An arrival time difference calculating means for calculating an arrival time difference that is a time difference between arrival times output from the plurality of receiving stations;
Position positioning means for positioning the target position from the arrival time difference calculated by the arrival time difference calculation means;
By substituting the target position measured by the position positioning means or the arrival time difference calculated by the arrival time difference calculating means into a filter for tracking processing, and performing the target tracking processing, A target tracking means for calculating a wake prediction value and a wake smooth value;
Display means for displaying the target track prediction value and the track smooth value calculated by the target tracking means;
Signal shielding determination means for determining whether signal shielding occurs between the target and the plurality of receiving stations;
Tracking process control means for controlling target tracking processing in the target tracking means according to the determination result of the signal shielding determination means,
The target tracking means performs a motion model integrated tracking process that integrates the processing result obtained from the tracking filter of the straight traveling model and the processing result obtained from the tracking filter of the turning model.
The tracking processing control means, set in accordance with the determination result of the signal blocking determination means, the processing results obtained from the tracking filter straight model, the weighting at the time of integrating the processing results obtained from the tracking filter of the turning model measuring position tracking device you characterized by. A plurality of receiving stations that receive signals transmitted from the target and output the arrival times of the signals;
An arrival time difference calculating means for calculating an arrival time difference that is a time difference between arrival times output from the plurality of receiving stations;
Position positioning means for positioning the target position from the arrival time difference calculated by the arrival time difference calculation means;
By substituting the target position measured by the position positioning means or the arrival time difference calculated by the arrival time difference calculating means into a filter for tracking processing, and performing the target tracking processing, A target tracking means for calculating a wake prediction value and a wake smooth value;
Display means for displaying the target track prediction value and the track smooth value calculated by the target tracking means;
Signal shielding determination means for determining whether signal shielding occurs between the target and the plurality of receiving stations;
Tracking process control means for controlling target tracking processing in the target tracking means according to the determination result of the signal shielding determination means,
The target tracking means includes a horizontal multiple motion model tracking process for tracking a target by combining a plurality of horizontal motion models, and a vertical multiple motion model for tracking a target by combining a plurality of vertical motion models. The tracking process is performed, and the processing result of the horizontal multi-motion model tracking process and the processing result of the vertical multi-motion model tracking process are integrated.
The tracking processing control unit, taking into account the determination result and terrain of the signal blocking determining means, the model transition probability of a multiple motion model tracking process of the model transition probability and the vertical direction of the multiple motion model tracking processing of the horizontal direction setting measuring position tracking device you characterized by. In the tracking process control means, when the motion model of the horizontal multi-motion model tracking process is a straight-ahead model and a turning model, and the motion model of the vertical multi-motion model tracking process is a plurality of straight-ahead models with constant altitude If the determination result of the signal shielding determination means indicates that signal shielding has occurred, the model transition probability from the straight model to the turning model in the horizontal multiple motion model tracking process is increased. 14. The positioning tracking apparatus according to claim 13, wherein the positioning tracking apparatus is configured to maintain a model transition probability of the vertical multiple motion model tracking process. When the motion model of the vertical multiple motion model tracking processing includes an ascending turning model and a descending turning model, the tracking processing control means is configured to convert the ascending turning model and the descending turning model according to a target altitude. The positioning tracking device according to claim 13, wherein it is determined whether to use the positioning tracking device.

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