CN103809449B - Aircraft multiloop model bunch Flutter Suppression Composite PID robust Controller Design method - Google Patents

Abstract

The invention provides a kind of aircraft multiloop model bunch Flutter Suppression Composite PID robust Controller Design method, the method directly determines to obtain by frequency sweep flight test the model cluster that amplitude-frequency in whole envelope and phase-frequency characteristic form under given differing heights, Mach number condition; Directly determine that open-loop cut-off frequency is interval according to the amplitude versus frequency characte in flight envelope; Directly determine with the phase margin corresponding to cutoff frequency interval interval according to the phase-frequency characteristic in flight envelope; By adding multistage PID controller and the phase margin index in aircraft whole envelope and the identification Method in System Discrimination determine multistage PID robust controller sum of series parameter value; Magnitude margin index in the full flight envelope of aircraft

Description

Design method of flutter suppression composite PID robust controller of aircraft multi-loop model cluster

Technical Field

The invention relates to a design method of an aircraft controller, in particular to a design method of a flutter suppression composite PID robust controller of an aircraft multi-loop model cluster, and belongs to the fields of measurement and control technology, flight mechanics and the like.

Background

The control of the take-off and landing process of the aircraft plays an important role in flight safety; because the flying speed of the aircraft is greatly changed in the taking-off and landing processes, the aircraft can also face a strong nonlinear problem even according to a longitudinal model; on the other hand, the control rudder of the aircraft has the phenomena of saturation, dead zone and the like; from the consideration of flight safety, when the system flies at ultra-low altitude (such as take-off/landing of an airplane), the controller must ensure that the system has certain stability margin, no overshoot and stability, so that the design of the ultra-low altitude flight controller is very complex, and the design of controlling the airplane cannot be directly applied by the existing control theory.

In the design of modern practical flight controllers, a small part of the design is designed by adopting a state space method, and most of the design is still designed by adopting a modern frequency method represented by a classical frequency domain method represented by PID and an inverse Nyquist array method. The modern control theory is characterized by a state space method, takes analytic calculation as a main means, and takes performance index realization as the optimal modern control theory, then a series of controller design methods such as an optimal control method, a model reference control method, an adaptive control method, a dynamic inverse control method, a feedback linearization method, a direct nonlinear optimization control, a variable gain control method, a neural network control method, a fuzzy control method, a robust control method and a multi-method combination control are developed, the published academic papers are in ten thousand, for example, 2011 GhasemiA designs a reentry aircraft controlled by an adaptive fuzzy sliding mode (GhasemiA, MoradiM, menhajmb.adaptivefuzzyingtoncontropresscontrolledesigne low-liftretryvehicle [ J ] journal of aeronautic engineering, sliding mode, 25(2): 210), and int3 year baoticebaotirebalance designs a nonlinear aircraft for a fuzzy pilot system, fuzzy pilot system engineering, and intelligent vehicle model system for unmanned aerial vehicle (mobile vehicle navigation system). 2013,24(3):499- & 509), many studies only stay in the idealized simulation study stage; the design has three problems that (1) because the ultra-low altitude operation stability test of the aircraft can not be carried out, an accurate mathematical model of a controlled object is difficult to obtain; (2) for evaluating important performance indexes of a flight control system such as stability margin specified by military standards, a state space method can not be expressed in an obvious form like a classical frequency method; (3) the controller structure is too complex, no constraints of actual controllers and flight states are considered, and the designed controller is not physically realizable.

The university scholark systematically and creatively researches how to popularize the frequency domain method into the design of a multivariable system, utilizes the concept of the advantage of the diagonal matrix to convert the multivariable problem into the design problem of a univariate system of a classical method which is well known by people, and then sequentially presents the methods of a Mayne sequence regression method, a MacFarlane characteristic trajectory method, an Owens parallel vector expansion method and the like. Especially when the computer aided design program with graphic display terminal is used, the experience and intelligence of the designer can be fully exerted to design the controller which not only meets the quality requirement, but also is physically realizable and has simple structure; the multivariate frequency method is improved and researched at home and abroad (a multivariate frequency domain design method of a high and high distance, Rocheng, Shenhui, Huidewen, flexible satellite attitude decoupling controller, aerospace science report, 2007, Vol.28(2), pp 442-447; Lithocarpus, Charpy, Tiaoling cloud, Tilt turning hypersonic cruise aircraft multivariate frequency domain method decoupling design, rocket and guidance science report, 2011, Vol.31(3), pp 25-28), however, the design method can consider that the conservatism is too large when the system is uncertain, and can not obtain reasonable design results under the condition of aircraft control rudder limitation; especially when the aircraft vibrates, the designed control system may have difficulty in ensuring the stability of the system.

In summary, the existing control method cannot design a stable low-altitude flight controller capable of suppressing flutter and having small overshoot according to stability margin indexes in a full-flight envelope when an aircraft model changes.

Disclosure of Invention

The invention provides a design method of a flutter suppression composite PID robust controller of an aircraft multi-loop model cluster, aiming at overcoming the technical defects that the existing method can not design a stable margin index meeting the full flight envelope under the condition that the model of the aircraft in the full flight envelope is changed greatly, the overshoot capable of suppressing the flutter is small, and the stable low-altitude flight controller is stableDirectly determining to obtain a model cluster formed by amplitude-frequency and phase-frequency characteristics in a full envelope by an over-scan frequency flight test; directly determining an open-loop cut-off frequency interval according to the amplitude-frequency characteristic in the flight envelope; directly determining a phase margin interval corresponding to the cut-off frequency interval according to the phase frequency characteristic in the flight envelope; determining the grade and parameter values of a multi-stage PID robust controller by adding the multi-stage PID controller, and determining a phase margin index in a full envelope of the aircraft and a model identification method in system identification; amplitude margin index in full flight envelope of aircraftCarrying out controller effect verification under the condition of given decibel number; a low-altitude flight robust controller which is in accordance with a full flight envelope and can restrain flutter, has small overshoot and is stable is designed from the concepts of phase margin and amplitude margin.

The technical scheme adopted by the invention for solving the technical problems is as follows: a design method for a flutter suppression composite PID robust controller of an aircraft multi-loop model cluster is characterized by comprising the following steps:

step 1, directly forming a model cluster of an operation control surface and a flight altitude in a full envelope of an aircraft by amplitude-frequency and phase-frequency characteristics in the full envelope of the aircraft allowed to fly through a sweep frequency flight test under the conditions of different given altitudes and Mach numbers, and obtaining the flutter frequency of the aircraft by crossing the flight envelope to obtain an open-loop transfer function model cluster matrix between the corresponding operation control surface and the flight altitude of the aircraft, wherein the open-loop transfer function model cluster matrix is as follows:

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is a positive integer and is a non-zero integer,is an independent variable of the laplacian transform,is the flying height of the aircraft,is a Mach number of the component (A),in order to be an uncertain vector,is composed ofA single-mode square matrix is adopted,is composed ofA polynomial diagonal matrix of the form,is composed ofA single-mode square matrix is adopted,in order to be a polynomial expression,is a positive integer;

selecting

The conditions are satisfied:

and

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is composed ofA single-mode square matrix is adopted,is composed ofA polynomial diagonal matrix of the form,is composed ofTo (1) aLine and firstThe elements of the column are, in turn,is composed ofTo (1) aLine and firstThe elements of the column are, in turn,,is composed ofA single-mode square matrix is adopted,in order to be a polynomial expression,is a phase angle mathematical sign;

the controller of the aircraft multi-circuit system is set as follows:

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is composed ofA diagonal matrix;is composed ofTo (1) aLine and firstThe elements of the column are, in turn,；

step 2, the controller，The design process of (2) is as follows:

(1) order toThe specific expression form is as follows:

the flutter frequency is:；

wherein

、

In order to be a polynomial expression,for the commonly used laplace-changed variable in the transfer function,respectively the altitude and the mach number,is the delay time of the pitch loop,to followThe gain of the variation is varied in such a way that,is a polynomialMiddle followThe cluster of coefficients that are varied is,is a polynomialMiddle followThe cluster of coefficients that are varied is,is an uncertainty in the model;

(2) judging at the uncertain part of the known modelThe method for directly determining the open-loop cut-off frequency interval according to the amplitude-frequency characteristic in the flight envelope comprises the following steps:

fromNamely, it isIs approximately asObtaining the open loop cut-off frequency of the system without the controllerMaximum value of solutionAnd minimum valueOpen loop cut-off frequency of controller-less systemThe interval is;

In the formula,is a positive real number, and the number of the real numbers,as a variable in the frequency characteristic,for the purpose of the imaginary part representation,is the angular frequency;

(3) judging at the uncertain part of the known modelAccording to the phase of flight envelopeFrequency characteristics, calculating maximum phase margin within envelopeAnd minimum phase margin within envelope

Directly determining a phase margin interval corresponding to the cut-off frequency interval as follows:；

wherein,is a positive real number;

(4) the transfer function of the candidate multi-stage PID controller is:

wherein N is an integer representing the number of stages of the multi-stage PID controller to be determined,、、 is a constant to be determined and is,a flutter suppression gain;

after the multi-stage PID controller is added,

fromNamely, it is

To obtain the open loop cut-off frequency after adding the controllerMaximum value of solutionAnd minimum valueOpen loop cut-off frequency after addition of controllerThe interval is，

Phase margin indicator in aircraft full envelopeUnder given conditions, the phase margin of the system is added after the multi-stage PID controller is addedIt should satisfy:

namely, the following conditions are satisfied:

at the same time, at the flutter frequencyThe following should also be satisfied:

namely, the following conditions are satisfied:

under the common constraint of the indexes and the maximum likelihood criterion or other criteria, the number of stages N and the constant of the multi-stage PID controller can be determined according to the maximum likelihood method or the identification method in the identification of the system model structure、、 And tremorGain of vibration suppression；

(5) Amplitude margin index within aircraft full envelopeIn the given case of decibels, the number of db,

fromNamely, it is

In obtaining the frequencyMaximum value of solutionAnd minimum value，The interval is，

And (3) judging:

namely, the following conditions are satisfied:

if so, completing the design of the flight controller; if not, increasing the number of stages of the multi-stage PID controller.

The invention has the beneficial effects that: based on the concepts of phase margin and amplitude margin, the parameters of the multi-stage PID robust controller are determined in the full-flight envelope according to the requirements of given phase margin and amplitude margin and a model identification method by adding the multi-stage PID controller, and the low-altitude flight robust controller which is consistent with the full-flight envelope and can restrain flutter, has small overshoot and is stable is designed.

The present invention will be described in detail with reference to examples.

Detailed Description

Step 1, linear sweep frequency signals are used under the conditions of different given altitudes and Mach numbers（In order to be the starting frequency,in order to cut-off the frequency of the frequency,，as sweep time) or log swept signals（In order to be the starting frequency,in order to cut-off the frequency of the frequency,and T is sweep frequency time), the amplitude-frequency and phase-frequency characteristics in a full envelope of the aircraft allowed to fly can be directly obtained, the flutter frequency of the aircraft can be obtained by crossing the flight envelope, and an open-loop transfer function model cluster matrix between the corresponding aircraft control surface and the flight altitude is obtained as follows:

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is a positive integer and is a non-zero integer,is an independent variable of the laplacian transform,is the flying height of the aircraft,is a Mach number of the component (A),in order to be an uncertain vector,is composed ofA single-mode square matrix is adopted,is composed ofA polynomial diagonal matrix of the form,is composed ofA single-mode square matrix is adopted,in order to be a polynomial expression,is a positive integer;

selecting

The conditions are satisfied:

and

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is composed ofA single-mode square matrix is adopted,is composed ofA polynomial diagonal matrix of the form,is composed ofTo (1) aLine and firstThe elements of the column are, in turn,is composed ofTo (1) aLine and firstThe elements of the column are, in turn,,is composed ofA single-mode square matrix is adopted,in order to be a polynomial expression,is a phase angle mathematical sign;

the controller of the aircraft multi-circuit system is set as follows:

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is composed ofA diagonal matrix;is composed ofTo (1) aLine and firstThe elements of the column are, in turn,；

step 2, the controller，The design process of (2) is as follows:

(1) order toThe specific expression form is as follows:

the flutter frequency is:；

wherein

、

In order to be a polynomial expression,for the commonly used laplace-changed variable in the transfer function,respectively the altitude and the mach number,is the delay time of the pitch loop,to followThe gain of the variation is varied in such a way that,is a polynomialMiddle followThe cluster of coefficients that are varied is,is a polynomialMiddle followThe cluster of coefficients that are varied is,is an uncertainty in the model;

(2) judging at the uncertain part of the known modelThe method for directly determining the open-loop cut-off frequency interval according to the amplitude-frequency characteristic in the flight envelope comprises the following steps:

fromNamely, it isIs approximately asObtaining the open loop cut-off frequency of the system without the controllerMaximum value of solutionAnd minimum valueOpen loop cut-off frequency of controller-less systemThe interval is;

In the formula,is a positive real number, and the number of the real numbers,as a variable in the frequency characteristic,for the purpose of the imaginary part representation,is the angular frequency;

(3) judging at the uncertain part of the known modelAccording to the phase frequency characteristic in the flight envelope, the maximum phase margin in the envelope is calculatedAnd minimum phase margin within envelope

Directly determining a phase margin interval corresponding to the cut-off frequency interval as follows:

；

wherein,is a positive real number;

(4) the transfer function of the candidate multi-stage PID controller is:

wherein N is an integer representing the number of stages of the multi-stage PID controller to be determined,、、 is a constant to be determined and is,a flutter suppression gain;

after the multi-stage PID controller is added,

fromNamely, it is

To obtain the open loop cut-off frequency after adding the controllerMaximum value of solutionAnd minimum valueOpen loop cut-off frequency after addition of controllerThe interval is，

Phase margin indicator in aircraft full envelopeUnder given conditions, the phase margin of the system is added after the multi-stage PID controller is addedIt should satisfy:

namely, the following conditions are satisfied:

at the same time, at the flutter frequencyThe following should also be satisfied:

namely, the following conditions are satisfied:

under the common constraint of the indexes and the maximum likelihood criterion or other criteria, the number of stages N and the constant of the multi-stage PID controller can be determined according to the maximum likelihood method or the identification method in the identification of the system model structure、、 Sum flutter suppression gain；

(5) Amplitude margin index within aircraft full envelopeIn the given case of decibels, the number of db,

fromNamely, it is

In obtaining the frequencyMaximum value of solutionAnd minimum value，The interval is，

And (3) judging:

namely, the following conditions are satisfied:

if so, completing the design of the flight controller; if not, increasing the number of stages of the multi-stage PID controller.

Claims (1)

1. A design method for a flutter suppression composite PID robust controller of an aircraft multi-loop model cluster is characterized by comprising the following steps:

step 1, directly forming a model cluster of an operation control surface and a flight altitude in a full envelope of an aircraft by amplitude-frequency and phase-frequency characteristics in the full envelope of the aircraft allowed to fly through a sweep frequency flight test under the conditions of different given altitudes and Mach numbers, and obtaining the flutter frequency of the aircraft by crossing the flight envelope to obtain an open-loop transfer function model cluster matrix between the corresponding operation control surface and the flight altitude of the aircraft, wherein the open-loop transfer function model cluster matrix is as follows:

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is a positive integer and is a non-zero integer,is an independent variable of the laplacian transform,is the flying height of the aircraft,is a Mach number of the component (A),in order to be an uncertain vector,is composed ofA single-mode square matrix is adopted,is composed ofA polynomial diagonal matrix of the form,is composed ofA single-mode square matrix is adopted,in order to be a polynomial expression,is a positive integer;

selecting

The conditions are satisfied:

and

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is composed ofA single-mode square matrix is adopted,is composed ofA polynomial diagonal matrix of the form,is composed ofTo (1) aLine and firstThe elements of the column are, in turn,is composed ofTo (1) aLine and firstThe elements of the column are, in turn,,is composed ofA single-mode square matrix is adopted,in order to be a polynomial expression,is a phase angle mathematical sign;

the controller of the aircraft multi-circuit system is set as follows:

wherein,is composed ofThe method comprises the following steps of (1) square matrix,is composed ofA diagonal matrix;is composed ofTo (1) aLine and firstThe elements of the column are, in turn,；

step 2, the controller，The design process of (2) is as follows:

(1) order toThe specific expression form is as follows:

the flutter frequency is:；

wherein

、

In order to be a polynomial expression,for the commonly used laplace-changed variable in the transfer function,respectively the altitude and the mach number,is the delay time of the pitch loop,to followThe gain of the variation is varied in such a way that,is a polynomialMiddle followThe cluster of coefficients that are varied is,is a polynomialMiddle followThe cluster of coefficients that are varied is,is an uncertainty in the model;

(2) judging at the uncertain part of the known modelThe method for directly determining the open-loop cut-off frequency interval according to the amplitude-frequency characteristic in the flight envelope comprises the following steps:

fromNamely, it isIs approximately asObtaining the open loop cut-off frequency of the system without the controllerMaximum value of solutionAnd minimum valueOpen loop cut-off frequency of controller-less systemThe interval is;

In the formula,is a positive real number, and the number of the real numbers,as a variable in the frequency characteristic,for the purpose of the imaginary part representation,is the angular frequency;

(3) judging at the uncertain part of the known modelAccording to the phase frequency characteristic in the flight envelope, the maximum phase margin in the envelope is calculatedAnd minimum phase margin within envelope

Directly determining a phase margin interval corresponding to the cut-off frequency interval as follows:；

wherein,is a positive real number;

(4) the transfer function of the candidate multi-stage PID controller is:

wherein N is an integer representing the number of stages of the multi-stage PID controller to be determined,、、 is a constant to be determined and is,a flutter suppression gain;

after the multi-stage PID controller is added,

fromNamely, it is

To obtain the open loop cut-off frequency after adding the controllerMaximum value of solutionAnd minimum valueOpen loop cut-off frequency after addition of controllerThe interval is，

Phase margin indicator in aircraft full envelopeUnder given conditions, the phase margin of the system is added after the multi-stage PID controller is addedIt should satisfy:

namely, the following conditions are satisfied:

at the same time, at the flutter frequencyThe following should also be satisfied:

namely, the following conditions are satisfied:

under the common constraint of the indexes and the maximum likelihood criterion or other criteria, the stages of the multi-stage PID controller can be determined according to the maximum likelihood method or the identification method in the system model structure identificationNumber N, constant、、 Sum flutter suppression gain；

(5) Amplitude margin index within aircraft full envelopeIn the given case of decibels, the number of db,

fromNamely, it is

In obtaining the frequencyMaximum value of solutionAnd minimum value，The interval is，

And (3) judging:

namely, the following conditions are satisfied:

if so, completing the design of the flight controller; if not, increasing the number of stages of the multi-stage PID controller.