
FUZZY LOGIC  AN INTRODUCTION
PART 3
This is the third in a series of six articles intended to share information and experience in the realm of fuzzy logic (FL) and its application. This article and the three to follow will take a more detailed look at how FL works by walking through a simple example. Informational references are included at the end of this article for interested readers.
In the last article the concept of linguistic variables was presented. The fuzzy parameters of error (commandfeedback) and errordot (rateofchangeoferror) were modified by the adjectives "negative", "zero", and "positive". To picture this, imagine the simplest practical implementation, a 3by3 matrix. The columns represent "negative error", "zero error", and "positive error" inputs from left to right. The rows represent "negative", "zero", and "positive" "errordot" input from top to bottom. This planar construct is called a rule matrix. It has two input conditions, "error" and "errordot", and one output response conclusion (at the intersection of each row and column). In this case there are nine possible logical product (AND) output response conclusions.
Although not absolutely necessary, rule matrices usually have an odd number of rows and columns to accommodate a "zero" center row and column region. This may not be needed as long as the functions on either side of the center overlap somewhat and continuous dithering of the output is acceptable since the "zero" regions correspond to "no change" output responses the lack of this region will cause the system to continually hunt for "zero". It is also possible to have a different number of rows than columns. This occurs when numerous degrees of inputs are needed. The maximum number of possible rules is simply the product of the number of rows and columns, but definition of all of these rules may not be necessary since some input conditions may never occur in practical operation. The primary objective of this construct is to map out the universe of possible inputs while keeping the system sufficiently under control.
The first step in implementing FL is to decide exactly what is to be controlled and how. For example, suppose we want to design a simple proportional temperature controller with an electric heating element and a variablespeed cooling fan. A positive signal output calls for 0100 percent heat while a negative signal output calls for 0100 percent cooling. Control is achieved through proper balance and control of these two active devices.
Linguistic rules describing the control system consist of two parts; an antecedent block (between the IF and THEN) and a consequent block (following THEN). Depending on the system, it may not be necessary to evaluate every possible input combination (for 5by5 & up matrices) since some may rarely or never occur. By making this type of evaluation, usually done by an experienced operator, fewer rules can be evaluated, thus simplifying the processing logic and perhaps even improving the FL system performance.
Linguistic variables are used to represent an FL system's operating parameters. The rule matrix is a simple graphical tool for mapping the FL control system rules. It accommodates two input variables and expresses their logical product (AND) as one output response variable. To use, define the system using plainEnglish rules based upon the inputs, decide appropriate output response conclusions, and load these into the rule matrix.
[9] "Fundamentals of Fuzzy Logic: Parts 1,2,3" by G. Anderson (SENSORS, MarchMay 1993).
[10] "Fuzzy Logic Flowers in Japan" by D.G. Schartz & G.J. Klir (IEEE Spectrum, July 1992, pp. 3235).
[11] "Fuzzy Logic Makes Guesswork of Computer Control" by Gail M. Robinson (Design News, Vol. 47, Nov. 28, 1991, pp. 21).
[12] "Fuzzy Logic Outperforms PID Controller" by P. Basehore (PCIM, March 1993).
File: FL_PART3.HTM 21398