KR102198761B1 - Dual mode autopilot apparatus and method for controlling attitude of unmanned air vehicles - Google Patents

Abstract

The present invention relates to a dual mode autopilot device for controlling the posture of an unmanned aerial vehicle separated from an aerial vehicle, and a posture control method of an unmanned aerial vehicle. The dual mode autopilot device comprises: a sensing unit for sensing the posture angle and the posture angular velocity of an unmanned aerial vehicle; a posture angular velocity control unit for changing the posture angular velocity of the unmanned aerial vehicle to allow the same to be the same as the posture angular velocity command value; a posture angle control unit for changing the posture angle of the unmanned aerial vehicle to allow the posture angle of the unmanned aerial vehicle to be the same as the posture angle command value; and a switching unit for selectively operating any one of two control units or switching the one to the other one while the one is operated. The switching unit selectively operates any one of the two control units, or switches the one to the other one when the one is operated, on the basis of at least one of the posture angle command value, the posture angle sensed by the sensing unit, and a maximum operating time.

Description

DUAL MODE AUTOPILOT APPARATUS AND METHOD FOR CONTROLLING ATTITUDE OF UNMANNED AIR VEHICLES}

The present invention relates to a dual mode autopilot device for controlling the attitude of an unmanned aerial vehicle separated from the vehicle and a method of controlling the attitude of the unmanned aerial vehicle.

Unmanned aerial vehicles launched from various mobile platforms such as ships, airplanes, and vehicles use aerodynamic wings to pass through several preset route points or follow straight lines to reach the target point.

Since the dynamic pressure is too low after the unmanned aerial vehicle is separated from the mobile platform, it is not possible to quickly change the attitude of the unmanned aerial vehicle toward the target point by control using aerodynamic wings (hereinafter, aerodynamic control).

To this end, if the speed increases by generating thrust, it is possible to control the attitude using aerodynamic control, but such a attitude control system may be vulnerable to disturbance during initial launch.

For example, an unmanned aerial vehicle launched from an airplane may generate thrust of an unmanned aerial vehicle in a state where the distance between the unmanned aerial vehicle and the airplane is sufficient for the safety of the airplane after launch. In this case, the attitude angle and the attitude angular velocity of the unmanned aerial vehicle at the start of thrust generation are changed by the disturbance.

The stability of the existing autopilot decreases due to the saturation of the actuator when the change in the attitude angle or the attitude angular velocity is large, and if the bandwidth of the existing autopilot is designed slowly to ensure stability, the performance of following the attitude angle due to disturbance decreases. It leads to a decrease in the trajectory tracking performance of the aerodynamic control section, preventing it from reaching the target point.

An object of the present invention is to provide a control device and a control method of an unmanned aerial vehicle for improving flight performance while securing the stability of the attitude control system.

In order to achieve the above object, there is provided a dual mode autopilot device for controlling the posture of an unmanned aerial vehicle separated from the vehicle. The dual-mode autopilot device includes a sensing unit that senses the attitude angle and the attitude angular velocity of the unmanned aerial vehicle, and an attitude angular velocity control unit that changes the attitude angular velocity of the unmanned aerial vehicle so that the attitude angular velocity of the unmanned aerial vehicle becomes the same as the attitude angular velocity command value. , Selectively operating any one of the attitude angle control unit and the two control units to change the attitude angle of the unmanned aerial vehicle so that the attitude angle of the unmanned aerial vehicle is the same as the attitude angle command value, or any one of the And a switching unit for switching to one of the one and the other, wherein the switching unit selects one of the two control units based on at least one of the attitude angle command value, the attitude angle sensed by the sensing unit, and a maximum operation time. It is characterized in that the operation is selectively operated or the one is switched to the other one while the one is operating.

In an embodiment, the switching unit may calculate a posture angle error using the posture angle command value and the posture angle sensed from the sensing unit, and select one of the two control units based on the posture angle error. .

In an embodiment, the switching unit selectively operates the posture angular velocity control unit when the posture angle error is greater than a first error threshold, and when the posture angle error is less than the first error threshold, the posture Each control unit can be selectively operated.

In an embodiment, the switching unit switches from the posture angular speed control unit to the posture angle control unit when the posture angle error becomes smaller than the second error threshold value while the posture angular velocity control unit is operating, and the second error threshold The value may be smaller than the first error threshold.

In one embodiment, even after the posture angular speed control unit operates for the maximum operation time, when the posture angle error is greater than the second error threshold, the switching unit may switch from the posture angular speed control unit to the posture angle control unit. have.

In an embodiment, the first error threshold may be calculated according to Equation 5 below.

[Equation 5]

In Equation 5, ε ₁ is the first error threshold, δmax is the driving limit angle of the attitude control structure, K _P is the proportional gain of the attitude angle controller, K _I is the integral gain, K _q is the differential gain, and t ₀ is the start time of the dual mode autopilot device, Δ is the sampling time of the dual mode autopilot device, and q(t) is the attitude angular velocity value sensed by the sensing unit.

In an embodiment, the maximum operation time may be calculated according to Equation 6 below.

[Equation 6]

In Equation 6, τ is the maximum operation time, ε ₁ is the first error threshold, and q _c is the attitude angular velocity command value.

In addition, the present invention provides a posture control method for controlling the posture of an unmanned aerial vehicle separated from the aircraft. The attitude control method includes the steps of separating the unmanned aerial vehicle from the vehicle, sensing the attitude angle and the attitude angular velocity of the unmanned vehicle, based on the attitude angle command value and the sensed attitude angle, among the attitude angular velocity control unit and the attitude angle control unit. Selectively operating any one and switching to the one and the other while the one is operating based on at least one of the attitude angle command value, the sensed attitude angle, and a preset maximum operation time. can do.

According to the present invention, it is possible to respond robustly to disturbances generated in the absence of a control means of an unmanned aerial vehicle. Through this, the present invention can secure both the stability and performance of the attitude control system mounted on the unmanned aerial vehicle.

1 is a block diagram showing a dual mode autopilot device according to the present invention.
2 is a conceptual diagram showing a control unit selection and switching algorithm.
3 is a relationship diagram showing the attitude angle, attack angle, and flight path angle of the unmanned aerial vehicle.

Hereinafter, exemplary embodiments disclosed in the present specification will be described in detail with reference to the accompanying drawings, but identical or similar elements are denoted by the same reference numerals regardless of reference numerals, and redundant descriptions thereof will be omitted. In describing the embodiments disclosed in the present specification, when it is determined that a detailed description of related known technologies may obscure the subject matter of the embodiments disclosed herein, the detailed description thereof will be omitted. In addition, the accompanying drawings are for easy understanding of the embodiments disclosed in the present specification, and the technical idea disclosed in the present specification is not limited by the accompanying drawings, and all modifications included in the spirit and scope of the present invention It should be understood to include equivalents or substitutes.

Hereinafter, a dual mode autopilot device according to the present invention will be described in detail.

1 is a block diagram showing a dual mode autopilot device according to the present invention.

The dual mode autopilot device according to the present invention is incorporated in an unmanned aerial vehicle. The dual mode autopilot device controls the attitude angle of the unmanned aerial vehicle when the unmanned aerial vehicle is separated from the vehicle.

To this end, the dual mode autopilot device according to an embodiment of the present invention includes a sensing unit, an attitude angular velocity control unit, an attitude angle control unit, and a switching unit. Each of the sensing unit, the attitude angle control unit, the attitude angle control unit, and the switching unit may be implemented by a separate computing device, and may include a memory for storing data.

Hereinafter, the components included in the dual mode autopilot device will be described in detail.

The sensing unit is configured to sense the attitude angle and the attitude angular velocity of the unmanned aerial vehicle. The sensing unit senses the attitude angle of the unmanned aerial vehicle in real time, and allows the sensed attitude angle to be utilized for control of the unmanned aerial vehicle. Since the posture angle and posture angular velocity measurement means utilizes a known means, a detailed description will be omitted.

The sensing unit may sense an angle with respect to each of the pitch, roll, and yaw axes, or may selectively sense an angle with respect to some of the three axes. The dual mode autopilot apparatus according to the present invention can control all of the attitude angles for each of the pitch, roll, and yaw axes, or control only the attitude angles for a specific axis.

Hereinafter, although an embodiment of controlling an attitude angle for a specific axis is disclosed, this is not limited to that the dual mode autopilot apparatus according to the present invention can perform only the attitude angle control for the specific axis. The dual mode autopilot apparatus according to the present invention can perform the attitude angle control for each of the three axes described above.

Meanwhile, the sensing unit may be configured to sense the speed of the unmanned aerial vehicle. For example, the sensing unit may be configured to sense the speed of each NED axis of the unmanned aerial vehicle. Since the above-described speed measurement means utilizes a known means, a detailed description will be omitted.

Meanwhile, the attitude angle controller is configured to control the movement of the attitude control structure provided in the unmanned aerial vehicle. For example, the attitude angle controller may be configured to control a driving angle of a flap, an elevator, and a rudder provided on a wing of the unmanned aerial vehicle.

The posture angle control unit controls the posture control structure based on a difference between the posture angle command value and the posture angle sensed by the sensor unit (hereinafter, posture angle error). The attitude angle controller receives an attitude angle command value from the vehicle, an external device, or another component built into the unmanned aerial vehicle, and controls the attitude control structure so that the attitude angle of the unmanned aerial vehicle becomes the same as the attitude angle command value. .

In one embodiment, the attitude angle control unit is configured in the form of a proportional-integral-differential controller that follows the attitude angle command value using the attitude angle information as well as the attitude angle velocity sensed from the sensor unit. I can. Specifically, the attitude angle controller may control the driving angle of the attitude control structure provided in the unmanned aerial vehicle according to Equation 1 below.

In Equation 1, δ is the driving angle value of the attitude control structure, K _P is the proportional gain of the attitude angle controller, K _I is the integral gain, and K _q is the differential gain. The gain values are values that vary depending on the speed and altitude of the unmanned aerial vehicle, but this is a design factor of the autopilot device, so it can be considered as a constant. It is assumed that the proportional gain, integral gain, and derivative gain described in this specification are all non-zero.

Meanwhile, in Equation 1, θ _c (t) is the attitude angle command value at point t, θ(t) is the attitude angle value measured by the sensing unit at time t, and q _t is the attitude angular velocity value measured by the sensing unit to be.

Meanwhile, the attitude angular velocity control unit is configured to control the movement of the attitude control structure provided in the unmanned aerial vehicle. For example, the attitude angular velocity control unit may be configured to control a driving angle of a flap, an elevator, and a rudder provided on a wing of an unmanned aerial vehicle.

The posture angular velocity control unit controls the posture control structure based on a difference value between the posture angular speed command value and the posture angular speed sensed from the sensor unit (hereinafter, the posture angular speed error). The attitude angular velocity control unit receives an attitude angular velocity command value from the vehicle, an external device, or other components built into the unmanned aerial vehicle, and the attitude provided in the unmanned aerial vehicle until the attitude angular velocity of the unmanned aerial vehicle becomes the same as the attitude angular velocity command value. Control the structure.

In one embodiment, the attitude angular velocity controller may be configured as a proportional gain controller to reduce an error between the attitude angular velocity sensed by the sensor unit and the angular velocity command. Specifically, the attitude angular velocity controller may control the driving angle of the attitude control structure provided in the unmanned aerial vehicle according to Equation 2 below.

In Equation 2 δ 'is a driving angle value of the orientation control structure, K _P' is a proportional gain, q _c (t) is a posture angular velocity command value, q (t) at time t of the posture angular velocity controller at time t This is the attitude angular velocity value measured by the sensing unit at.

Based on the above, the difference between the attitude angle control unit and the attitude angle speed control unit will be described.

Since the attitude angle command value (θ _c (t)) is the final target value of the attitude angle of the unmanned aerial vehicle, it can be regarded as an unchanged value. For this reason, it is difficult to control the attitude angle error value. When the attitude angle error value increases, a situation in which it is difficult for the attitude angle controller to control the attitude of the unmanned aerial vehicle occurs.

The situation in which it is difficult for the attitude angle controller to control the unmanned aerial vehicle will be described in more detail with reference to Equation 3 below.

In Equation 3, e(t) is θ _c (t)-θ(t), which means an error value of an attitude angle. t ₀ is the point at which the dual mode autopilot device starts to control the attitude control structure, and Δ is the sampling time of the dual mode autopilot device. δmax means the driving limit angle of the attitude control structure.

In Equation 3, the left side denotes a driving angle of the attitude control structure controlled by the attitude angle controller. The driving angle must be less than or equal to the driving limit angle of the attitude control structure. The attitude angle error becomes very large, and when the driving angle becomes larger than the driving limit angle, the attitude angle controller cannot control the attitude of the unmanned aerial vehicle.

On the other hand, since the attitude angular velocity control unit is controlled by the attitude angular velocity command value, it is possible to control the unmanned aerial vehicle even in a situation where the attitude angle error value is large. This will be described in detail with reference to Equation 4 below.

In Equation 4, the left side is a driving angle of the attitude control structure controlled by the attitude angular velocity controller. Here, since the posture angle command value (q _c (t ₀ )) can be changed according to the situation, the posture angle speed error value (q _c (t ₀ )-q(t ₀ )) can be controlled. Specifically, when the q(t ₀ ) value changes rapidly, the posture angular velocity error value can be reduced by adjusting the q _c (t ₀ ) value to be close to q(t ₀ ). For this reason, it is possible to control the unmanned aerial vehicle while preventing the drive angle from reaching δmax by using the attitude angular velocity controller.

As described above, while the attitude angle controller enables precise control of the unmanned aerial vehicle through relatively many variables, when the attitude angle error value increases due to disturbance, the unmanned aerial vehicle cannot be controlled. On the other hand, the attitude angular velocity control unit is relatively inferior in precision, but can control the unmanned aerial vehicle even when the attitude angle error value increases due to disturbance.

The present invention makes it possible to secure both stability and performance of a posture control system of an unmanned aerial vehicle by using the above-described two control units in an appropriate situation.

To this end, the dual mode autopilot device according to the present invention includes a switching unit. The switching unit is configured to selectively operate one of the two control units or to switch one of the two control units to the other while the one is operating.

Specifically, the switching unit selectively operates any one of the two control units based on at least one of the attitude angle command value, the attitude angle sensed from the sensing unit, and a preset maximum operation time, or During operation, it switches to one of the above and the other.

2 is a conceptual diagram showing a control unit selection and switching algorithm.

In FIG. 2, θ _c (t) is the attitude angle command value at the point t, θ(t) is the attitude angle value measured by the sensing unit at the point t, and t ₀ is the driving start point of the dual mode autopilot device, ε ₁ is a first error threshold, ε ₂ is a second error threshold, and τ is a maximum operating time.

1 and 2, the switching unit determines whether the posture angle error value θ _c (t)-θ (t) is greater than the first error threshold. When the posture angle error value is greater than the first error threshold value, the switching unit causes the posture angle speed controller to be selectively driven. Meanwhile, when the posture angle error value is less than or equal to the first error threshold, the switching unit selectively drives the posture angle control unit.

On the other hand, when the posture angle error value is less than or equal to the second error threshold while the posture angular speed control unit is being driven, the switching unit drives the posture angle control unit instead of the posture angular speed control unit. On the other hand, the switching unit causes the attitude angle control unit to be driven instead of the attitude angular speed control unit when the attitude angular velocity control unit is driven longer than the maximum operation time.

Here, the first error threshold may be calculated by Equation 5 below.

In Equation 5, δmax is the driving limit angle of the attitude control structure, K _P is the proportional gain of the attitude angle controller, K _I is the integral gain, K _q is the differential gain, and t ₀ is the start of driving the dual mode autopilot device. Is the time point, Δ is the sampling time of the dual mode autopilot device, and q(t) is the attitude angular velocity value sensed by the sensing unit.

According to Equation 5, ε ₁ denotes a maximum posture angle error value at which the driving angle applied to the posture control structure by the posture angle controller may not reach the limit drive angle. That is, when the attitude angle error value exceeds the first error threshold value, it means that the unmanned aerial vehicle cannot be controlled by the attitude angle controller.

The present invention selectively drives the attitude angular velocity control unit only in a situation where the unmanned aerial vehicle cannot be controlled by the attitude angle control unit when driving the dual mode autopilot device.

Meanwhile, the second error threshold may be smaller than the first error threshold. That is, the present invention switches the attitude angle speed control unit to the attitude angle control unit in a state where the posture angle error value is sufficiently small.

Meanwhile, the maximum operating time may be expressed by Equation 6 below.

Equation 6 refers to an estimated time required for the posture angular velocity controller to correct the posture angle error value corresponding to the first error threshold. If the posture angle error value is not corrected even though the posture angular speed control unit is driven during the maximum operation time, it means that the unmanned aerial vehicle cannot be stabilized by the posture angular speed control unit, and thus the posture angle control unit is switched to a more precise control.

In the present invention, by adopting a method of dropping the unmanned aerial vehicle by the air vehicle, not only does the impact of the launching have a large effect, but also the hardware for controlling the unmanned aerial vehicle can be configured very simply. However, when this method is selected, the free fall time is lengthened so that the vehicle does not collide with the unmanned aerial vehicle, and at this time, due to an aerodynamic effect, a maximum difference of 180 degrees can be made compared to the initial posture immediately before the unmanned vehicle is dropped.

When the initial posture angle of the unmanned aerial vehicle is a very large posture angle that we do not want (for example, the posture angle we want is 0 degrees and the initial posture angle is 180 degrees), an aerodynamic phenomenon called phantom yaw occurs. When the angle of attack of the phantom yaw is large, unexpected side forces occur due to the asymmetry of the flow. At this time, if a previously known control method is used, control of the unmanned aerial vehicle becomes impossible.

According to the present invention, it is possible to attenuate the phantom yaw effect that may occur when the initial attitude angle of the unmanned aerial vehicle is very large. For example, the present invention can suppress the generation of side force by applying an attitude angular velocity command value at which the angle of attack is minimized to the attitude angular velocity control unit.

This will be described in more detail with reference to FIG. 3.

3 is a relationship diagram showing the attitude angle, attack angle, and flight path angle of the unmanned aerial vehicle.

In Fig. 3, V is the velocity vector, X _B , Z _B are the body coordinate system of the vehicle, X _I , Z _I are the inertial coordinate system of the vehicle, O is the origin of the vehicle, α is the angle of attack of the unmanned vehicle, and γ is the unmanned The flight path angle of the vehicle, θ is the attitude angle of the unmanned aerial vehicle.

The relationship between θ, α and γ is shown in Equation 7 below.

When both sides of Equation 7 are differentiated, it is as shown in Equation 8 below.

When the attitude angular velocity control unit is driven and the attitude angular velocity command value θ _c '(i.e., q _c ) is applied as the same value as γ', the attitude angular velocity control unit sets the attitude angular velocity θ'to the attitude angular velocity command value θ _c '(i.e. , γ'), and ultimately α'converges to zero.

Here, since θ'means an attitude angular velocity, it can be measured by the sensing unit, and γ'can be calculated by measuring the speed of each reference axis of the unmanned aerial vehicle. Therefore, it is possible to apply the command value of the attitude angular velocity according to the value of γ'.

As described above, if the attitude angular velocity controller is used, the angle of attack generated by the change of the attitude is not increased, and the angle of attack is bound, so that the phantom yaw phenomenon can be avoided.

As described above, according to the present invention, it is possible to respond robustly to disturbances generated in the absence of a control means of an unmanned aerial vehicle. Through this, the present invention can secure both the stability and performance of the attitude control system mounted on the unmanned aerial vehicle.

It is obvious to a person skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit and essential features of the present invention.

In addition, the detailed description above should not be construed as restrictive in all respects and should be considered as illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

Claims (8)

In the dual mode autopilot device for controlling the attitude of the unmanned aerial vehicle separated from the vehicle,
A sensing unit for sensing the attitude angle and the attitude angular velocity of the unmanned aerial vehicle;
An attitude angular velocity control unit for changing the attitude angular velocity of the unmanned aerial vehicle so that the attitude angular velocity of the unmanned aerial vehicle becomes the same as the attitude angular velocity command value;
An attitude angle control unit for changing the attitude angle of the unmanned aerial vehicle so that the attitude angle of the unmanned aerial vehicle becomes the same as the attitude angle command value; And
And a switching unit that selectively operates one of the two control units or switches to one of the two control units while the one is operating,
The switching unit,
Based on at least one of the attitude angle command value, the attitude angle sensed by the sensing unit, and the maximum operation time, one of the two control units is selectively operated, or the one of the two control units is operated. Dual mode autopilot device, characterized in that switching to the other one. The method of claim 1,
The switching unit,
The attitude angle error is calculated using the attitude angle command value and the attitude angle sensed from the sensing unit,
A dual mode autopilot apparatus, characterized in that one of the two control units is selected based on the posture angle error. The method of claim 2,
The switching unit,
When the posture angle error is greater than the first error threshold, the posture angle speed controller is selectively operated,
When the posture angle error is smaller than the first error threshold, the posture angle control unit is selectively operated. The method of claim 3,
The switching unit,
If the posture angle error becomes smaller than the second error threshold while the posture angular speed control unit is operating, the posture angular speed control unit is switched to the posture angle control unit,
The second error threshold is a dual mode autopilot apparatus, characterized in that less than the first error threshold. The method of claim 4,
If the posture angle error is greater than the second error threshold even after the posture angular speed control unit operates during the maximum operation time,
The switching unit,
A dual mode autopilot device, characterized in that switching from the attitude angular velocity control unit to the attitude angle control unit. The method of claim 5,
The first error threshold is a dual-mode autopilot device, characterized in that calculated according to the following equation (5).
[Equation 5]

In Equation 5, ε ₁ is the first error threshold, δmax is the driving limit angle of the attitude control structure, K _P is the proportional gain of the attitude angle controller, K _I is the integral gain, K _q is the differential gain, and t ₀ is the start time of the dual mode autopilot device, Δ is the sampling time of the dual mode autopilot device, and q(t) is the attitude angular velocity value sensed by the sensing unit. The method of claim 6,
The maximum operating time is a dual mode autopilot device, characterized in that calculated according to the following equation (6).
[Equation 6]

In Equation 6, τ is the maximum operation time, ε ₁ is the first error threshold, and q _c is the attitude angular velocity command value. In the attitude control method for controlling the attitude of the unmanned aerial vehicle separated from the vehicle,
Separating the unmanned aerial vehicle from the vehicle;
Sensing the attitude angle and the attitude angular velocity of the unmanned aerial vehicle;
Selectively operating any one of a posture angular velocity control unit and a posture angle control unit based on the posture angle command value and the sensed posture angle; And
The attitude control method of the unmanned aerial vehicle comprising the step of switching to the one and the other one while the one is operating based on at least one of the attitude angle command value, the sensed attitude angle, and a preset maximum operation time.

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