CN108427277A - Based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor export constrained control method - Google Patents

Abstract

It is a kind of based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor export constrained control method, for the dynamic system of quadrotor, a kind of asymmetric time-varying cut type constraint liapunov function anyway, a kind of quadrotor based on the compound constraint liapunov function of asymmetric time-varying tangent cosine of design is selected to export constrained control method.The design that cut type constrains liapunov function anyway of asymmetric time-varying is to avoid excessive overshoot in a certain range to ensure that the output of system can limit, while can also reduce arrival time.So as to improve the dynamic response performance of quadrotor system.The present invention provide it is a kind of based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor export constrained control method, make system have preferable dynamic response process.

Description

Based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor flight Device exports constrained control method

Technical field

The present invention relates to it is a kind of based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor Constrained control method is exported, quadrotor system is made to have preferable dynamic response process.

Background technology

The one kind of quadrotor as rotary aircraft, it is small with its, mobility is good, design is simple, system The advantages that of low cost is made, the extensive concern of domestic and international university, research institution, company has been attracted.However, since quadrotor is flown Device is small and light-weight, is in-flight vulnerable to external disturbance, how to realize the High Performance Motion Control to quadrotor Have become a hot issue.For the control problem of quadrotor, there are many control methods, such as PID control, Active Disturbance Rejection Control, sliding formwork control, Reverse Step Control etc..

Wherein Reverse Step Control has been widely used for nonlinear system, and advantage includes fast response time, easy to implement, right The uncertain robustness etc. with external disturbance of system.Traditional Reverse Step Control only considers the stability of quadrotor Can, there is no pay close attention to its transient response performance too much.Therefore, traditional backstepping control method makes quadrotor system Application in a practical situation has very big obstruction.To solve this problem, the Reverse Step Control based on constraint liapunov function Method is suggested, and this method can effectively improve the mapping of quadrotor system in a practical situation.

Invention content

In order to improve quadrotor system transients performance, the present invention provides one kind being based on asymmetric time-varying arc tangent The quadrotor that type constrains liapunov function exports constrained control method, reduces overshoot and overshoot time, makes There are one good dynamic response performances for quadrotor system tool.

In order to solve the above-mentioned technical problem the technical solution proposed is as follows：

It is a kind of that based on asymmetric time-varying, cut type constrains the limited control of quadrotor output of liapunov function anyway Method processed, includes the following steps：

Step 1, the dynamic model of quadrotor system, initial value, sampling time and the control of initialization system are established Parameter processed, process are as follows：

1.1 determine from the body coordinate system based on quadrotor system to the transfer square of the inertial coordinate based on the earth Battle array T：

Wherein, φ, θ, ψ are roll angle, pitch angle, the yaw angle of quadrotor respectively, indicate aircraft successively around The angle of each reference axis rotation of inertial coodinate system；

Dynamic model during the translation of 1.2 quadrotors is as follows：

Wherein, x, y, z indicate three positions of the quadrotor under inertial coodinate system, U respectively_fIndicate that quadrotor flies The input torque of row device, m are the quality of quadrotor, and g indicates acceleration of gravity；

Formula (1) is substituted into formula (2) to obtain：

Dynamic model in 1.3 quadrotor rotation processes is：

Wherein, τ_x,τ_y,τ_zRespectively represent the moment components of each axis on body coordinate system, I_xx,I_yy,I_zzMachine is indicated respectively The component of the rotary inertia of each axis under body coordinate system, × indicate multiplication cross, ω_pIndicate rolling angular speed, ω_qIndicate pitch angle Speed, ω_rIndicate yaw rate,Indicate rolling angular acceleration,Indicate pitching angular acceleration,Indicate that yaw angle adds Speed；

In view of aircraft is in low-speed operations or floating state, it is believed that Therefore formula (4) is rewritten as：

Simultaneous formula (3) and formula (5), the kinetic model for obtaining quadrotor are：

Wherein, u_x=cos φ sin θ cos ψ+sin φ sin ψs, u_y=cos φ sin θ sin ψ-sin φ cos ψ；

1.4, according to formula (6), define φ, and the desired value of θ is respectively：

Wherein, φ_dFor the expected signal value of φ, θ_dFor θ expected signal values, arcsin is arcsin function；

Step 2, in each sampling instant, calculating position tracking error and its first derivative；Posture angle tracking is calculated to miss Difference and its first derivative；Design position and posture angle controller, process are as follows：

2.1 define z tracking errors and its first derivative：

Wherein, z_dIndicate the desired signal of z；

2.2 define q₁：

2.3 design constraint liapunov function V₁₁：

Wherein, K_a1,K_b1For time-varying parameter：

2.4 solve formula (10) first derivative, obtain：

Wherein,

α₁For virtual controlling amount, expression formula is：

Wherein, k₁₁,β₁For normal number；

Formula (13) is substituted into formula (12), is obtained：

2.5 design liapunov function V₁₂For：

Solution formula (15) first derivative parallel connection is vertical (14), obtains：

Wherein

Formula (17) and formula (6) are substituted into formula (16), obtained：

2.6 design U_f：

Wherein, k₁₂For normal number；

2.7 define x, and y tracking errors are respectively e₂,e₃, then have：

Wherein, x_d,y_dX, the desired signal of y are indicated respectively；

2.8 define q₂,q₃：

2.9 design constraint liapunov function V₂₁,V₃₁：

Wherein, K_a2,K_b2,K_a3,K_b3For time-varying parameter：

2.10 solve formula (23) first derivative, obtain：

Wherein

α₂,α₃For virtual controlling amount, expression formula is：

Wherein, k₂₁,k₃₁,β₂,β₃For normal number；

Formula (26) is substituted into formula (25), is obtained：

2.11 design liapunov function V₂₂,V₃₂For：

The first derivative parallel connection vertical (27) of solution formula (28)：

Wherein

Formula (30) and formula (6) are substituted into formula (29), obtained：

2.12 designing u_x,u_y：

Wherein, k₂₂,k₃₂For normal number；

2.13 define posture angle tracking error and its first derivative：

Wherein, j=4,5,6, x₄=φ, x₅=θ, x₆=ψ, x_4dIndicate the desired value of φ, x_5dIndicate the desired value of θ, x_6d Indicate the desired value of ψ, e₄Indicate the tracking error of φ, e₅Indicate the tracking error of β, e₆Indicate the tracking error of ψ；

2.14 defining q_j：

2.15 design constraint liapunov function：

Wherein, K_aj,K_bjFor time-varying parameter：

2.16 solve formula (35) first derivative, obtain：

Wherein

α_jFor virtual controlling amount, expression formula is：

Wherein, k_j1,β_jFor normal number；

Formula (38) is substituted into formula (37), is obtained：

2.17 design liapunov function V_j2For：

The first derivative parallel connection of solution formula (40) is vertical (39), obtains：

Wherein

Formula (42) and formula (6) are substituted into formula (41), obtained：

2.18 design τ by formula (43)_x,τ_y,τ_z：

Wherein, k₄₂,k₅₂,k₆₂For normal number；

Step 3, the stability of quadrotor system is verified, process is as follows：

Formula (19) is substituted into formula (18) by 3.1, is obtained：

Formula (32) is substituted into formula (31) by 3.2, is obtained：

Formula (44) is substituted into formula (43) by 3.3, is obtained

3.4 know that quadrotor system is stable by (45), (46), (47).

The present invention is based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor output it is limited Control method improves the mapping of system, reduces overshoot and arrival time.

The present invention technical concept be：For the dynamic system of quadrotor, when design one kind being based on asymmetric The quadrotor for becoming cut type constraint liapunov function anyway exports constrained control method.Asymmetric time-varying cut type anyway The design for constraining liapunov function is to ensure that the output of system can limit in a certain range, avoid excessive Overshoot, while arrival time can also be reduced.So as to improve the dynamic response performance of quadrotor system.

Advantage of the present invention is：Overshoot is reduced, arrival time is reduced, improves mapping.

Description of the drawings

Fig. 1 is the position tracking effect diagram of the present invention.

Fig. 2 is the attitude angle tracking effect schematic diagram of the present invention.

Fig. 3 is that the positioner of the present invention inputs schematic diagram.

Fig. 4 is that the posture angle controller of the present invention inputs schematic diagram.

Fig. 5 is the control flow schematic diagram of the present invention.

Specific implementation mode

The present invention will be further described below in conjunction with the accompanying drawings.

- Fig. 5 referring to Fig.1, it is a kind of based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor flight Device exports constrained control method, includes the following steps：

Step 1, the dynamic model of quadrotor system, initial value, sampling time and the control of initialization system are established Parameter processed, process are as follows：

1.1 determine from the body coordinate system based on quadrotor system to the transfer square of the inertial coordinate based on the earth Battle array T：

Wherein, φ, θ, ψ are roll angle, pitch angle, the yaw angle of quadrotor respectively, indicate aircraft successively around The angle of each reference axis rotation of inertial coodinate system；

Dynamic model during the translation of 1.2 quadrotors is as follows：

Wherein, x, y, z indicate three positions of the quadrotor under inertial coodinate system, U respectively_fIndicate that quadrotor flies The input torque of row device, m are the quality of quadrotor, and g indicates acceleration of gravity；

Formula (1) is substituted into formula (2) to obtain：

Dynamic model in 1.3 quadrotor rotation processes is：

Wherein, τ_x,τ_y,τ_zRespectively represent the moment components of each axis on body coordinate system, I_xx,I_yy,I_zzMachine is indicated respectively The component of the rotary inertia of each axis under body coordinate system, × indicate multiplication cross, ω_pIndicate rolling angular speed, ω_qIndicate pitch angle Speed, ω_rIndicate yaw rate,Indicate rolling angular acceleration,Indicate pitching angular acceleration,Indicate that yaw angle adds Speed；

In view of aircraft is in low-speed operations or floating state, attitude angle variation is smaller, it is believed thatTherefore formula (4) is rewritten as：

Simultaneous formula (3) and formula (5), the kinetic model for obtaining quadrotor are：

Wherein, u_x=cos φ sin θ cos ψ+sin φ sin ψs, u_y=cos φ sin θ sin ψ-sin φ cos ψ；

1.4, according to formula (6), define φ, and the desired value of θ is respectively：

Wherein, φ_dFor the expected signal value of φ, θ_dFor θ expected signal values, arcsin is arcsin function；

Step 2, in each sampling instant, calculating position tracking error and its first derivative；Posture angle tracking is calculated to miss Difference and its first derivative；Design position and posture angle controller, process are as follows：

2.1 define z tracking errors and its first derivative：

Wherein, z_dIndicate the desired signal of z；

2.2 define q₁：

2.3 design constraint liapunov function V₁₁：

Wherein, K_a1,K_b1For time-varying parameter：

2.4 solve formula (10) first derivative, obtain：

Wherein,

α₁For virtual controlling amount, expression formula is：

Wherein, k₁₁,β₁For normal number；

Formula (13) is substituted into formula (12), is obtained：

2.5 design liapunov function V₁₂For：

Solution formula (15) first derivative parallel connection is vertical (14), obtains：

Wherein

Formula (17) and formula (6) are substituted into formula (16), obtained：

2.6 design U_f：

Wherein, k₁₂For normal number；

2.7 define x, and y tracking errors are respectively e₂,e₃, then have：

Wherein, x_d,y_dX, the desired signal of y are indicated respectively；

2.8 define q₂,q₃：

2.9 design constraint liapunov function V₂₁,V₃₁：

Wherein, K_a2,K_b2,K_a3,K_b3For time-varying parameter：

2.10 solve formula (23) first derivative, obtain：

Wherein

α₂,α₃For virtual controlling amount, expression formula is：

Wherein, k₂₁,k₃₁,β₂,β₃For normal number；

Formula (26) is substituted into formula (25), is obtained：

2.11 design liapunov function V₂₂,V₃₂For：

The first derivative parallel connection vertical (27) of solution formula (28)：

Wherein

Formula (30) and formula (6) are substituted into formula (29), obtained：

2.12 designing u_x,u_y：

Wherein, k₂₂,k₃₂For normal number；

2.13 define posture angle tracking error and its first derivative：

Wherein, j=4,5,6, x₄=φ, x₅=θ, x₆=ψ, x_4dIndicate the desired value of φ, x_5dIndicate the desired value of θ, x_6d Indicate the desired value of ψ, e₄Indicate the tracking error of φ, e₅Indicate the tracking error of θ, e₆Indicate the tracking error of ψ；

2.14 defining q_j：

2.15 design constraint liapunov function：

Wherein, K_aj, K_bjFor time-varying parameter：

2.16 solve formula (35) first derivative, obtain：

Wherein

α_jFor virtual controlling amount, expression formula is：

Wherein, k_j1, β_jFor normal number；

Formula (38) is substituted into formula (37), is obtained：

2.17 design liapunov function V_j2For：

The first derivative parallel connection of solution formula (40) is vertical (39), obtains：

Wherein

Formula (42) and formula (6) are substituted into formula (41), obtained：

2.18 design τ by formula (43)_x, τ_y, τ_z：

Wherein, k₄₂, k₅₂, k₆₂For normal number；

Step 3, the stability of quadrotor system is verified, process is as follows：

Formula (19) is substituted into formula (18) by 3.1, is obtained：

Formula (32) is substituted into formula (31) by 3.2, is obtained：

Formula (44) is substituted into formula (43) by 3.3, is obtained

3.4 know that quadrotor system is stable by (45), (46), (47).

The feasibility of extracting method in order to verify, the emulation knot that The present invention gives the control methods on MATLAB platforms Fruit：

Parameter is given below：M=1.1kg, g=9.81N/kg in formula (2)；In formula (4), I_xx=1.22kgm², I_yy= 1.22kg·m², I_zz=2.2kgm²；Z in formula (8), formula (20) and formula (33)_d=0.5, x_d=1, y_d=1, ψ_d=1；Formula (13), k in formula (26) and formula (38)₁₁=2, k₂₁=2, k₃₁=2, k₄₁=2, k₅₁=2, k₆₁=2；β₁=0.1, β₂=0.1, β₃ =0.1, β₄=0.1, β₅=0.1, β₆=0.1；K in formula (19), formula (32) and formula (44)₁₂=2, k₂₂=2, k₃₂=2, k₄₂= 2,k₅₂=2, k₆₂=2；Formula (11), formula (24), formula (35) k_b1=k_b2=k_b3=k_b4=k_b5=k_b6=4.5+0.1sint；k_a1 =k_a2=k_a3=k_a4=k_a5=k_a6=4+

0.1sint。

From Fig. 1 and Fig. 2 it is found that it is 7.10 seconds that system, which has good transient response, arrival time, overshoot 0.

In conclusion based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor output by Limit control method can effectively improve the mapping of quadrotor system.

Described above is the excellent effect of optimization that one embodiment that the present invention provides is shown, it is clear that the present invention is not only It is limited to above-described embodiment, in the premise without departing from essence spirit of the present invention and without departing from range involved by substantive content of the present invention Under it can be made it is various deformation be implemented.

Claims (1)

1. it is a kind of based on asymmetric time-varying anyway cut type constrain liapunov function quadrotor export constrained control Method, which is characterized in that the described method comprises the following steps：

Step 1, the dynamic model of quadrotor system, initial value, sampling time and the control ginseng of initialization system are established Number, process are as follows：

1.1 determine from the body coordinate system based on quadrotor system to the transfer matrix of the inertial coordinate based on the earth T：

Wherein, φ, θ, ψ are roll angle, pitch angle, the yaw angle of quadrotor respectively, indicate aircraft successively around inertia The angle of each reference axis rotation of coordinate system；

Dynamic model during the translation of 1.2 quadrotors is as follows：

Wherein, x, y, z indicate three positions of the quadrotor under inertial coodinate system, U respectively_fIndicate quadrotor Input torque, m be quadrotor quality, g indicate acceleration of gravity；

Formula (1) is substituted into formula (2) to obtain：

Dynamic model in 1.3 quadrotor rotation processes is：

Wherein, τ_x,τ_y,τ_zRespectively represent the moment components of each axis on body coordinate system, I_xx,I_yy,I_zzIndicate that body is sat respectively The component of the rotary inertia of each axis under mark system, × indicate multiplication cross, ω_pIndicate rolling angular speed, ω_qIndicate rate of pitch, ω_rIndicate yaw rate,Indicate rolling angular acceleration,Indicate pitching angular acceleration,Indicate yaw angular acceleration；

In view of aircraft is in low-speed operations or floating state, it is believed that Therefore formula (4) is rewritten as：

Simultaneous formula (3) and formula (5), the kinetic model for obtaining quadrotor are：

Wherein, u_x=cos φ sin θ cos ψ+sin φ sin ψs, u_y=cos φ sin θ sin ψ-sin φ cos ψ；

1.4, according to formula (6), define φ, and the desired value of θ is respectively：

Wherein, φ_dFor the expected signal value of φ, θ_dFor θ expected signal values, arcsin is arcsin function；

Step 2, in each sampling instant, calculating position tracking error and its first derivative；Calculate posture angle tracking error and Its first derivative；Design position and posture angle controller, process are as follows：

2.1 define z tracking errors and its first derivative：

Wherein, z_dIndicate the desired signal of z；

2.2 define q₁：

2.3 design constraint liapunov function V₁₁：

Wherein, K_a1,K_b1For time-varying parameter：

2.4 solve formula (10) first derivative, obtain：

Wherein,

α₁ For virtual controlling amount, expression formula is：

Wherein, k₁₁,β₁For normal number；

Formula (13) is substituted into formula (12), is obtained：

2.5 design liapunov function V₁₂For：

Solution formula (15) first derivative parallel connection is vertical (14), obtains：

Wherein

Formula (17) and formula (6) are substituted into formula (16), obtained：

2.6 design U_f：

Wherein, k₁₂For normal number；

2.7 define x, and y tracking errors are respectively e₂,e₃, then have：

Wherein, x_d,y_dX, the desired signal of y are indicated respectively；

2.8 define q₂,q₃：

2.9 design constraint liapunov function V₂₁,V₃₁：

Wherein, K_a2,K_b2,K_a3,K_b3For time-varying parameter：

2.10 solve formula (23) first derivative, obtain：

Wherein

α₂,α₃For virtual controlling amount, expression formula is：

Wherein, k₂₁,k₃₁,β₂,β₃For normal number；

Formula (26) is substituted into formula (25), is obtained：

2.11 design liapunov function V₂₂,V₃₂For：

The first derivative parallel connection vertical (27) of solution formula (28)：

Wherein

Formula (30) and formula (6) are substituted into formula (29), obtained：

2.12 designing u_x,u_y：

Wherein, k₂₂,k₃₂For normal number；

2.13 define posture angle tracking error and its first derivative：

Wherein, j=4,5,6, x₄=ψ, x₅=θ, x₆=ψ, x_4dIndicate the desired value of φ, x_5dIndicate the desired value of θ, x_6dIndicate ψ Desired value, e₄Indicate the tracking error of φ, e₅Indicate the tracking error of θ, e₆Indicate the tracking error of ψ；

2.14 defining q_j：

2.15 design constraint liapunov function：

Wherein, K_aj,K_bjFor time-varying parameter：

2.16 solving formula (35) first derivative, obtain：

Wherein

α_jFor virtual controlling amount, expression formula is：

Wherein, k_j1,β_jFor normal number；

Formula (38) is substituted into formula (37), is obtained：

2.17 design liapunov function V_j2For：

The first derivative parallel connection of solution formula (40) is vertical (39), obtains：

Wherein

Formula (42) and formula (6) are substituted into formula (41), obtained：

2.18 design τ by formula (43)_x,τ_y,τ_z：

Wherein, k₄₂,k₅₂,k₆₂For normal number；

Step 3, the stability of quadrotor system is verified, process is as follows：

Formula (19) is substituted into formula (18) by 3.1, is obtained：

Formula (32) is substituted into formula (31) by 3.2, is obtained：

Formula (44) is substituted into formula (43) by 3.3, is obtained

3.4 know that quadrotor system is stable by (45), (46), (47).