Crc Press Mechatronics Handbook 2002 By Laxxuss Episode 3 Part 9 ppsx

The dynamics and measurement functions are linearized about a known reference state, t, which is related to the true environment state, Xt, via 28.3 The LKF state estimate is related to

The true dynamic system is described by a general first-order, ordinary differential equation

(28.2)

where f is the nonlinear dynamics function that incorporates all significant deterministic effects of the environment, αααα is a vector of parameters used in the model, and w(t) is a random process that accounts for the noise present from mismodeling in f or from the quantum uncertainty of the universe, depending

on the accuracy of the deterministic model in use

With these general models available, a linear Kalman filter (LKF) may be derived in a discrete-time formulation The dynamics and measurement functions are linearized about a known reference state, (t), which is related to the true environment state, X(t), via

(28.3) The LKF state estimate is related to the true difference by

(28.4)

where the “ ” denotes the state estimate (or filter state), is the estimation error, and “±” indicates whether the estimate and error are evaluated instantaneously before (−) or after (+) measurement update

at discrete time t k

It is important to emphasize that the LKF filter state is the estimate of the difference between the environment and the reference state The LKF mode of operation will therefore carry along a reference state and the filter state between measurement updates Only the filter state is at the time of measurement update Figure 28.1 illustrates the generalized relationship between the true, reference, and filter states

in an LKF estimating a two-dimensional trajectory

Linearization of Dynamic and Measurement System Models

The dynamics and measurement functions may be linearized about the known reference state, (t), according to

(28.5)

(28.6)

FIGURE 28.1 LKF tracking of a two-dimensional

trajectory.

Reference Trajectory

True Trajectory State Estimate

Estimation Error

X˙ t( ) = f X t( ( ),αααα,t) w t+ ( )

X˜

X˜ t ( ) x t+ ( ) = X t( )

xˆk

± ( )

xk dx k

± ( )

+

=

X˜

f X,( αααα, t )  f X˜ t( ( ),αααα, t ) F X˜ t+ ( ( ),αααα, t )x t ( ) w t+ ( )

h X,( αααα, t )  h X˜ t( ( ),ββββ, t ) H X˜ t+ ( ( ),ββββ, t )x t ( ) v t+ ( )

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The true dynamic system is described by a general first-order, ordinary differential equation

(28.2)

where f is the nonlinear dynamics function that incorporates all significant deterministic effects of the environment, αααα is a vector of parameters used in the model, and w(t) is a random process that accounts for the noise present from mismodeling in f or from the quantum uncertainty of the universe, depending

on the accuracy of the deterministic model in use

With these general models available, a linear Kalman filter (LKF) may be derived in a discrete-time formulation The dynamics and measurement functions are linearized about a known reference state, (t), which is related to the true environment state, X(t), via

(28.3) The LKF state estimate is related to the true difference by

(28.4)

where the “ ” denotes the state estimate (or filter state), is the estimation error, and “±” indicates whether the estimate and error are evaluated instantaneously before (−) or after (+) measurement update

at discrete time t k

It is important to emphasize that the LKF filter state is the estimate of the difference between the environment and the reference state The LKF mode of operation will therefore carry along a reference state and the filter state between measurement updates Only the filter state is at the time of measurement update Figure 28.1 illustrates the generalized relationship between the true, reference, and filter states

in an LKF estimating a two-dimensional trajectory

Linearization of Dynamic and Measurement System Models

The dynamics and measurement functions may be linearized about the known reference state, (t), according to

(28.5)

(28.6)

FIGURE 28.1 LKF tracking of a two-dimensional

trajectory.

Reference Trajectory

True Trajectory State Estimate

Estimation Error

X˙ t( ) = f X t( ( ),αααα,t) w t+ ( )

X˜

X˜ t ( ) x t+ ( ) = X t( )

xˆk

± ( )

xk dx k

± ( )

+

=

X˜

f X,( αααα, t )  f X˜ t( ( ),αααα, t ) F X˜ t+ ( ( ),αααα, t )x t ( ) w t+ ( )

h X,( αααα, t )  h X˜ t( ( ),ββββ, t ) H X˜ t+ ( ( ),ββββ, t )x t ( ) v t+ ( )

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Digital Signal Processing

for Mechatronic

Applications 29.1 Introduction

29.2 Signal Processing Fundamentals

Continuous-Time Signals • Discrete-Time Signals

29.3 Continuous-Time to Discrete-Time Mappings

Discretization •s-Plane to z-Plane Mappings

• Frequency Domain Mappings

29.4 Digital Filter Design

IIR Filter Design • FIR Filter Design • Computer-Aided Design of Digital Filters • Filtering Examples

29.5 Digital Control Design

Digital Control Example

29.1 Introduction

Most engineers work in the world of mechatronics as there are relatively few systems that are purely mechanical or electronic There are a variety of means by which electrical systems augment mechanical systems and vise versa For example, most microprocessors found in a computer today have some sort

of heat sink and perhaps a fan attached to them to keep them within their operational temperature zone Electrical systems are widely employed to monitor and control a wide variety of mechanical systems With the advent of inexpensive digital processing chips, digital filtering and digital control for mechanical systems is becoming commonplace Examples of this can be seen in every automobile and most household appliances For example, sensor signals used in monitoring and controlling of mechanical systems require some form of signal processing This signal processing can range from simply “cleaning-up” the signal using a low pass filter to more advanced analyses such as torque and power monitoring in a DC servo motor This chapter presents a brief overview of digital signal processing methods suitable for mechanical systems Since this chapter is limited in space, it does not give any derivation or details of analysis For

a more detailed discussion, see references [1,2]

29.2 Signal Processing Fundamentals

A few fundamental concepts on signal processing must be introduced before a discussion of filtering or control can be undertaken

Bonnie S Heck

Georgia Institute of Technology

Thomas R Kurfess

Georgia Institute of Technology

30

Control System Design Via H 2 Optimization 30.1 Introduction

30.2 General Control System Design Framework

Central Idea: Design Via Optimization • The Signals • General H2 Optimization Problem • Generalized Plant • Closed Loop Transfer Function

Matrices • Overview of H2 Optimization Problems to Be Considered

30.3 H2 Output Feedback Problem

Hamiltonian Matrices

30.4 H 2 State Feedback Problem

Generalized Plant Structure for State Feedback • State Feedback Assumptions

30.5 H 2 Output Injection Problem

Generalized Plant Structure for Output Injection • Output Injection Assumptions

30.6 Summary

30.1 Introduction

This chapter addresses control system design via H2 (quadratic) optimization A unifying framework based on the concept of a generalized plant and weighted optimization permits designers to address state feedback, state estimation, dynamic output feedback, and more general structures in a similar fashion The framework permits one to easily incorporate design parameters and/or weighting functions that may

be used to influence the outcome of the optimization, satisfy desired design specifications, and systematize the design process Optimal solutions are obtained via well-known Riccati equations; e.g., Control Algebraic Riccati Equation (CARE) and Filter Algebraic Riccati Equation (FARE) While dynamic weight-ing functions increase the dimension of the Riccati equations beweight-ing solved, solutions are readily obtained using today’s computer-aided design software (e.g., MATLAB, robust control toolbox, µ-synthesis tool-box, etc.)

In short, H2 optimization generalizes all of the well-known quadratic control and filter design methodologies:

• Linear Quadratic Regulator (LQR) design methodology [7,11],

• Kalman–Bucy Filter (KBF) design methodology [5,6],

• Linear Quadratic Gaussian (LQG) design methodology [4,10,11]

H2optimization may be used to systematically design constant gain state feedback control laws, state estimators, dynamic output controllers, and much more

Armando A Rodriguez

Arizona State University

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