Self-Smoothing Functional Estimation

Yake, Bronson Thomas

13 December 2002

Analysis of measured data is often required when there is no deep understanding of the mathematics that accurately describes the process being measured. Additionally, realistic estimation of the derivative of measured data is often useful. Current techniques of accomplishing this type of data analysis are labor intensive, prone to significant error, and highly dependent on the expertise of the engineer performing the analysis. The ?Self-Smoothing Functional Estimation? (SSFE) algorithm was developed to automate the analysis of measured data and to provide a reliable basis for the extraction of derivative information. In addition to the mathematical development of the SSFE algorithm, an example is included in Chapter III that illustrates several of the innovative features of the SSFE and associated algorithms. Conclusions are drawn about the usefulness of the algorithm from an engineering perspective and additional possible uses are mentioned.

trajectory

estimation

filter

curve fit

Settling-Time Improvements in Positioning Machines Subject to Nonlinear Friction Using Adaptive Impulse Control

Hakala, Tim

31 January 2006

A new method of adaptive impulse control is developed to precisely and quickly control the position of machine components subject to friction. Friction dominates the forces affecting fine positioning dynamics. Friction can depend on payload, velocity, step size, path, initial position, temperature, and other variables. Control problems such as steady-state error and limit cycles often arise when applying conventional control techniques to the position control problem. Studies in the last few decades have shown that impulsive control can produce repeatable displacements as small as ten nanometers without limit cycles or steady-state error in machines subject to dry sliding friction. These displacements are achieved through the application of short duration, high intensity pulses. The relationship between pulse duration and displacement is seldom a simple function. The most dependable practical methods for control are self-tuning; they learn from online experience by adapting an internal control parameter until precise position control is achieved. To date, the best known adaptive pulse control methods adapt a single control parameter. While effective, the single parameter methods suffer from sub-optimal settling times and poor parameter convergence. To improve performance while maintaining the capacity for ultimate precision, a new control method referred to as Adaptive Impulse Control (AIC) has been developed. To better fit the nonlinear relationship between pulses and displacements, AIC adaptively tunes a set of parameters. Each parameter affects a different range of displacements. Online updates depend on the residual control error following each pulse, an estimate of pulse sensitivity, and a learning gain. After an update is calculated, it is distributed among the parameters that were used to calculate the most recent pulse. As the stored relationship converges to the actual relationship of the machine, pulses become more accurate and fewer pulses are needed to reach each desired destination. When fewer pulses are needed, settling time improves and efficiency increases. AIC is experimentally compared to conventional PID control and other adaptive pulse control methods on a rotary system with a position measurement resolution of 16000 encoder counts per revolution of the load wheel. The friction in the test system is nonlinear and irregular with a position dependent break-away torque that varies by a factor of more than 1.8 to 1. AIC is shown to improve settling times by as much as a factor of two when compared to other adaptive pulse control methods while maintaining precise control tolerances.

control

position

adaptive

impulsive

settling-time

nonlinear friction

pulses

displacements

precise

tolerances

log-spaced

update

distributed

learning

Coulomb

Stribeck

Tomizuka

Yang

AIC

PID

MRAC

STR

RTAI

Linux

FreeBSD

kernel modules

microcontroller

convergence

practical

self-tuning

methods

techniques

limit-cycles

steady-state

error

zero

stable

stability

bound

envelope

partitioned

scheme

lookup-table

multi-point

adaptation

repeatable

mean

servo

motor

exponential

square-law

rise-time

real-time

log-log interpolation

pro-forma

curve-fit

sensitivity

compliance

variable

static

dynamic response

torque

acceleration

velocity

optical encoder

parameters

evolution

fixed-law

enhanced split

weighting

initialization

trajectory

layered processes

Mechanical Engineering