JP2017112730A - State estimation device and state estimation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To estimate a state of a control target more appropriately without using a sensor.SOLUTION: A state estimation device 1 comprises a power supply 10, a motor 20a, a state estimation inductor 30, a controller 40, and a voltmeter 50. The state estimation inductor 30 is connected in series to a circuit that connects between the power supply 10 for supplying a power to the motor 20a that is a control target and the motor 20a. The voltmeter 50 detects a both-end voltage of the state estimation inductor 30. The controller 40 estimates a state of the motor 20a on the basis of both-end of the voltage of the state estimation inductor 30 detected by the voltmeter 50.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a state estimation device and a state estimation method for estimating a state of a control target.

Conventionally, there has been a demand for sensorless motors (motors) in robots and the like from the viewpoints of improving fault tolerance, reducing costs, downsizing devices, and the like. In particular, when operating a motor equipped in a robot, etc. in a poor environment, such as an environment contaminated with chemical substances that affect the operation of the sensor or an environment where strong radioactivity exists, the state of the motor is grasped by the sensor. Therefore, the sensorless motor is an extremely important issue.
Here, in order to reduce the sensor of a motor in a robot or the like, a technique for estimating an angle of a part of a robot including a motor by a change in inductance is known (for example, see Patent Document 1).

JP 2003-164187 A

However, in the technique described in Patent Document 1, the angle of the robot part is estimated by identifying the inductance of an actuator (motor) that drives the robot. In such a method, it is necessary to superimpose an input for inductance estimation on an input necessary for control, which causes problems in control performance and estimation accuracy. In addition, since the structure is such that the inductance varies depending on the angle, the applicable actuator structure is limited.
As described above, in the conventional technique, it is difficult to appropriately estimate the state of the control target without using a sensor.

  The subject of this invention is estimating the state of a control object more appropriately, without using a sensor.

In order to solve the above problem, a state estimation device according to an aspect of the present invention includes:
A power source that supplies power to a motor to be controlled and an inductor connected in series to a circuit that connects the motor;
Voltage detecting means for detecting a voltage across the inductor;
Estimating means for estimating the state of the motor based on the voltage across the inductor detected by the voltage detecting means;
It is characterized by providing.

  According to the present invention, it is possible to more appropriately estimate the state of the controlled object without using a sensor.

It is a circuit diagram which shows the basic principle of this invention. It is a block diagram which shows the specific structure of the state estimation apparatus 1 to which this invention is applied. It is a schematic diagram which shows the experimental result at the time of estimating a state using this invention, FIG. 3 (A) is a figure which shows the estimation result of a force, FIG.3 (B) is a figure which shows the estimation result of a torque.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
First, the basic principle applied to the state estimation device and the state estimation method according to the present invention will be described.
[Basic principles]
FIG. 1 is a circuit diagram showing the basic principle of the present invention.
As shown in FIG. 1, in the state estimation device 1 according to the present invention, a circuit including a power source 10, a control target 20, and a state estimation inductor 30 is configured.
Among these, the power supply 10 and the state estimation inductor 30 can be installed on the control side away from the controlled object 20. For example, when the controlled object 20 is installed in an environment that is difficult to enter due to chemical substances, radioactivity, or the like, the power supply 10 and the state estimating inductor 30 can be installed in a control room or the like in an accessible environment.

In FIG. 1, a power supply 10 is a power supply whose supply voltage is variable, and supplies power according to the load of the control target 20.
The control target 20 is configured by, for example, an actuator (motor) or the like, and operates by power supplied from the power supply 10. Note that the control target 20 generates a counter electromotive force according to the load during operation.
The state estimation inductor 30 is connected in series to a loop including the power supply 10 and the control target 20, and the same current as the current flowing through the power supply 10 and the control target 20 (hereinafter referred to as “drive current” as appropriate) flows. It has become. The state estimation inductor 30 generates an electromotive force according to the self-inductance when a drive current flows.

As shown in FIG. 1, when the inertia of the control target 20 (motor) is J, the angular velocity is ω, the generated torque is Tm, and the load torque is Tl, the equation of motion of the control target 20 is expressed by the equation (1). .
J · dω = Tm−Tl (1)
However, dω is a time derivative of ω.

Further, when the applied voltage of the controlled object 20 is Vm, the internal resistance is R, the current is I, and the counter electromotive force is E, the voltage relationship in the controlled object 20 is expressed by Expression (2).
Vm = R · I + E (2)

Here, the counter electromotive force E in the equation (2) is expressed by the equation (3) using the counter electromotive force constant Kt and the angular velocity ω.
E = Kt · ω (3)

Then, Expression (2) is expressed as Expression (4).
Vm = R · I + Kt · ω (4)
When changes in the internal resistance and the back electromotive force constant Kt of the controlled object 20 are extremely small and can be regarded as being substantially constant, Expression (5) is obtained by differentiating both sides of Expression (4) with respect to time. It is done.
dVm = R · dI + Kt · dω (5)

When equation (5) is solved for angular velocity, equation (6) is obtained.
dω = (dVm−R · dI) / Kt (6)
When the state estimation inductor 30 is connected in series with the controlled object 20, when the inductance of the state estimation inductor 30 is _L , the voltage _VL applied to the state estimation inductor 30 is expressed as shown in Expression (7). Is done.
V _L = L · dI (7)

Since the current flowing through the controlled object 20 and the current flowing through the state estimating inductor 30 are equal, substituting the current differential value dI of Expression (7) into Expression (6) yields Expression (8).
dω = (ΔVm−R · (V _L / L)) / Kt
= (ΔVm · LR−V _L ) / (Kt · L) (8)

In Expression (8), ΔVm is the amount of change in the supply voltage of the power supply 10 (that is, the amount of change in the command value to the power supply 10), and _VL is the voltage across the state estimation inductor 30 (measured value).
Thereby, the angular acceleration dω of the controlled object 20 can be estimated from the equation (8) by the parameters (ΔVm and V _L ) that can be acquired on the control side.
That is, in the configuration of the present invention, since the state of the control target 20 is reflected in the state estimation inductor 30 installed on the control side, the control target 20 can be controlled by paying attention to the state of the state estimation inductor 30. The state of the controlled object 20 can be estimated on the control side without providing a sensor.

In addition, it is possible to configure robust control such as a disturbance observer using the angular acceleration dω of the controlled object 20.
In addition, robust control can be performed by obtaining the angular acceleration dω of the control target 20, so that the position and force of the control target 20 can be controlled with high accuracy. As a result, it is possible to transmit a force sense input to the controlled object 20 to the control side, and to realize sensorless motors in a remotely operated robot.
Furthermore, since the external force applied to the controlled object 20 can be estimated by a disturbance observer or the like, an angle control loop based on the angular acceleration and a torque control loop based on the estimated external force can be configured.

[Specific configuration]
Next, a specific configuration of the state estimation device 1 to which the present invention is applied will be described.
FIG. 2 is a block diagram showing a specific configuration of the state estimation apparatus 1 to which the present invention is applied.
As shown in FIG. 2, the state estimation device 1 includes a power supply 10, a motor 20 a as a control target 20, a state estimation inductor 30, a control unit 40, and a voltmeter 50.
Among these, the power supply 10 and the state estimation inductor 30 are referred to the description in FIG. 1, and the description is omitted here.

  The motor 20a is, for example, an actuator that drives a robot manipulator, and outputs a force corresponding to the power supplied from the power supply 10 to the outside. Further, the motor 20a is installed at a position remote from the power source 10, the state estimation inductor 30, the control unit 40, and the voltmeter 50 (a point separated by a distance or a point separated by an obstacle such as a wall). . However, in the present invention, the distance from the power source 10 or the like to the motor 20a is not particularly questioned.

The control unit 40 controls the power supply 10 by inputting a command value of power supplied from the power supply 10. At this time, the control unit 40 estimates the angular acceleration dω (or force to be output) of the motor 20a based on the equation (8) based on the voltage _VL across the state estimation inductor 30 input from the voltmeter 50, A command value of power supplied from the power supply 10 is determined.
The voltmeter 50 measures the voltage _VL across the state estimating inductor 30 and outputs the measurement result to the control unit 40. Note that the both-ends voltage _VL of the state estimation inductor 30 measured by the voltmeter 50 is A / D (Analog to Digital) converted and output to the control unit 40.

[Operation]
Next, the operation of the state estimation device 1 will be described.
First, the control unit 40 calculates a command value to the power source 10 corresponding to the target value of the force (or position) output from the motor 20 a and inputs the command value to the power source 10.
Then, the power supply 10 applies a voltage Vm corresponding to the command value to the motor 20a, and the motor 20a outputs a force (or position) according to the applied voltage Vm.
At this time, a current I that is common to the power supply 10, the motor 20a, and the state estimation inductor 30 flows through the state estimation device 1, and the control unit 40 controls the internal resistance R of the motor 20a, the back electromotive force constant Kt, the state estimation. inductance L of the inductor 30, and calculates the angular acceleration dω corresponding across voltage V _L variation ΔVm and state estimation inductor 30 of the supply voltage of the power source 10 (see equation (8)).

By calculating each acceleration dω, it is possible to appropriately estimate the state of the motor 20a such as speed (integration of acceleration), position (double integration of acceleration) or force.
That is, the state of the motor 20a can be estimated more appropriately without using a sensor.
Thereby, for example, it becomes possible to control the manipulator of the robot by bilateral control while reproducing the force sense in the motor 20a on the control side and transmitting the accurate force sense.
When the present invention is used for bilateral control, the difference in acceleration between the master side and the slave side becomes substantially zero, and the force sense is appropriately transmitted. At this time, the absolute positions on the master side and the slave side are operated by the operator while visually recognizing the position with a camera or the like, so that there is no problem in transmitting the force sense.

Further, in the above-described embodiment, the state estimation device 1 estimates the state of the motor 20a without using a sensor and resets the state of the motor 20a in order to reset the accumulated error that occurs when estimating the state of the motor 20a. It is also possible to provide a reset sensor (detection means) for detection. In this case, it is sufficient that the sensor for resetting is a sensor having a coarser detection accuracy than a sensor for detecting the state of the motor 20a as in the prior art. Since the reset sensor is a sensor with a coarser detection accuracy, even if it is installed in a poor environment, the influence of the environment on the estimation accuracy is smaller than the conventional sensor that detects the state of the motor 20a. Become. Further, since the reset sensor only needs to be able to reset the accumulated error, it is possible to use a sensor of a different type from the conventional sensor that detects the state of the motor 20a. Therefore, a type of sensor that is not easily affected by the environment in which the motor 20a is installed can be selected as a reset sensor.
Thus, by providing the reset sensor, higher estimation accuracy can be realized.

[effect]
3A and 3B are schematic diagrams showing experimental results when the state is estimated using the present invention, FIG. 3A is a diagram showing a force estimation result, and FIG. 3B is a diagram showing a torque estimation result. .
As shown in FIG. 3A, with respect to the force command value (solid line), the measured value (dotted line) measured using the sensor and the estimated value (dashed line) estimated using the present invention are almost equal. Match.
Further, as shown in FIG. 3B, with respect to the torque command value (solid line), a measured value (dotted line) measured using a sensor and an estimated value (dashed line) estimated using the present invention Is almost the same.

Thus, according to the present invention, it is possible to more appropriately estimate the state of the controlled object without using a sensor.
Therefore, according to the present invention, failure and false detection of the sensor unit are eliminated, so that the fault tolerance can be improved, and the volume corresponding to the sensor is not required, so that the apparatus can be downsized. Further, according to the present invention, since the weight corresponding to the sensor is eliminated, the weight of the device can be reduced, and the cost for installing the sensor is not required, so that the cost of the device can be reduced.

  That is, the present invention realizes high-precision control of position and force without arranging a sensor on the drive side, and improves fault tolerance and cost reduction that the current robot technology has, and downsizing the apparatus. Such a problem can be solved. This makes it possible to use robots in the field that were difficult to introduce in the past and to develop cheaper robots, and is expected to be applied in a wide range of fields.

[Specific application examples]
Next, a specific application example of the state estimation device 1 will be described.
(1) Application to an actuator inside a nuclear reactor The present invention can be applied to an actuator used inside a nuclear reactor.
That is, a manipulator having an actuator can be arranged inside the nuclear reactor, and a manipulator control unit, a power source, and a state estimation inductance can be arranged in the nuclear reactor control room.
When a manipulator equipped with a sensor is used in a nuclear reactor, the sensor fails in a short period due to radioactivity, and it is necessary to frequently replace the manipulator.
On the other hand, by applying the configuration of the present invention, it is possible to estimate the state of the manipulator in the same manner as in the case where the state of the manipulator is measured by the sensor, and to reduce the manipulator replacement frequency. .

(2) Application to an actuator in a narrow space The present invention can be applied to an actuator used in a narrow space such as the inside of a human body.
It is difficult to provide an encoder having a relatively large size in a manipulator used in a narrow space such as a manipulator used in endoscopic surgery inside a human body.
In such a case, the force sense of the manipulator can be transmitted to the control unit side by applying the configuration of the present invention and arranging the state estimation inductor 30 in series with the actuator that drives the manipulator. It becomes.

(3) Application to the actuator in the realization of the human physical action To realize the human physical action, the current state (acceleration, velocity, position, etc.) of the actuator is used as an input, and the position (or velocity) or force The operation of the actuator can be determined by performing computation in at least one of the areas (see, for example, International Patent Application PCT / JP2014 / 073083 by the inventors).
In such a case, applying the present invention and providing the state estimation inductor 30 makes it possible to estimate the current position of the actuator without providing a sensor for detecting the current position of the actuator.

(4) Application to real-time state estimation under severe operating conditions The present invention can be applied to a motor that drives an excavator that performs excavation work of a tunnel or the like.
In tunnel excavation work, it may hit hard layers such as bedrock due to changes in geology, and if it is dug as it is, it may cause malfunction of the excavator. Therefore, at the excavation site, the excavator is stopped as appropriate, and for example, several days are spent to check the formation. The efficiency of the construction work will be reduced due to such confirmation of the formation.
On the other hand, by applying the present invention to the motor that drives the excavator, the force output from the motor to the formation can be estimated in real time without providing a sensor. In addition, when a sensor is installed in such an excavator, since the operation conditions are severe, sensor failures frequently occur.
As a result, it is detected in real time that there has been a change in geology, so there is no need to stop the excavator unnecessarily, and the efficiency of construction work can be improved.

The state estimation device 1 configured as described above includes a power supply 10, a motor 20a, a state estimation inductor 30, a control unit 40, and a voltmeter 50.
The state estimation inductor 30 is connected in series to a circuit connecting the power supply 10 that supplies power to the motor 20a to be controlled and the motor 20a.
The voltmeter 50 detects the voltage across the inductor 30 for state estimation.
The controller 40 estimates the state of the motor 20 a based on the voltage across the state estimating inductor 30 detected by the voltmeter 50.
With such a configuration, a current common to the power source 10, the motor 20 a, and the state estimation inductor 30 flows through the state estimation device 1, and the control unit 40 controls the motor 20 a based on the voltage across the state estimation inductor 30. Estimate the state.
Therefore, the state of the motor 20a can be estimated more appropriately without using a sensor.

The power supply 10, the state estimation inductor 30 and the motor 20a are installed at remote positions.
Thereby, the state of the motor 20a can be estimated using the state estimation inductor 30 installed outside the poor environment or the like without providing the motor 20a installed in the poor environment or the like.

Further, the control unit 40 estimates the state of the motor 20a based on the change in the command value of the voltage applied to the motor 20a and the voltage across the state estimation inductor 30.
As a result, the state of the motor 20a can be estimated from the command value or measurement value that can be easily acquired.

Moreover, the control part 40 estimates the angular acceleration or acceleration in the motor 20a.
Thereby, it is possible to more appropriately estimate the angular acceleration or acceleration necessary for transmitting the force sense.

Moreover, the control part 40 estimates the torque or force in the motor 20a.
Thereby, it is possible to more appropriately control the force in the manipulator of the robot.

Further, the state estimation device 1 includes a reset sensor.
The reset sensor detects the state of the motor 20a in order to reset the estimation error by the control unit 40.
The control unit 40 resets the accumulated error when estimating the state of the motor 20a based on the detection result of the resetting sensor.
Thereby, higher estimation accuracy can be realized in the state estimation device 1.

  In addition, the said embodiment has shown an example to which this invention is applied, and does not limit the technical scope of this invention. That is, the present invention can be modified in various ways such as omission and replacement without departing from the gist of the present invention, and can take various embodiments other than the above-described embodiments. Various embodiments that the present invention can take and modifications thereof are included in the invention described in the scope of claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 State estimation apparatus, 10 power supply, 20 Control object, 20a Motor, 30 State estimation inductor, 40 Control part, 50 Voltmeter

Claims (7)

A power source that supplies power to a motor to be controlled and an inductor connected in series to a circuit that connects the motor;
Voltage detecting means for detecting a voltage across the inductor;
Estimating means for estimating the state of the motor based on the voltage across the inductor detected by the voltage detecting means;
A state estimation device comprising:   The state estimation apparatus according to claim 1, wherein the power source, the inductor, and the motor are installed at remote positions.   3. The state estimation according to claim 1, wherein the estimation unit estimates a state of the motor based on a change in a command value of a voltage applied to the motor and a voltage across the inductor. apparatus.   The state estimation apparatus according to claim 1, wherein the estimation unit estimates angular acceleration or acceleration in the motor.   The state estimation apparatus according to claim 1, wherein the estimation unit estimates a torque or a force in the motor. Detecting means for detecting a state of the motor to reset an estimation error by the estimating means;
6. The state estimation device according to claim 1, wherein the estimation unit resets an accumulated error when estimating the state of the motor based on a detection result of the detection unit. . A state estimation method for estimating a state of a motor to be controlled,
Detecting a voltage across an inductor connected in series to a circuit connecting the motor and a power source that supplies power to the motor,
A state estimation method, wherein the state of the motor is estimated based on the detected voltage across the inductor.

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