Concept class

In computational learning theory in mathematics, a concept over a domain X is a total Boolean function over X. A concept class is a class of concepts. Concept classes are a subject of computational learning theory.

Concept class terminology frequently appears in model theory associated with probably approximately correct (PAC) learning.^[1] In this setting, if one takes a set Y as a set of (classifier output) labels, and X is a set of examples, the map $c:X\to Y$ , i.e. from examples to classifier labels (where $Y=\{0,1\}$ and where c is a subset of X), c is then said to be a concept. A concept class $C$ is then a collection of such concepts.

Given a class of concepts C, a subclass D is reachable if there exists a sample s such that D contains exactly those concepts in C that are extensions to s.^[2] Not every subclass is reachable.^[2]^[why?]

Background[edit]

A sample $s$ is a partial function from $X$ ^{[clarification needed]} to $\{0,1\}$ .^[2] Identifying a concept with its characteristic function mapping $X$ to $\{0,1\}$ , it is a special case of a sample.^[2]

Two samples are consistent if they agree on the intersection of their domains.^[2] A sample $s'$ extends another sample $s$ if the two are consistent and the domain of $s$ is contained in the domain of $s'$ .^[2]

Examples[edit]

Suppose that $C=S^{+}(X)$ . Then:

the subclass $\{\{x\}\}$ is reachable with the sample $s=\{(x,1)\}$ ;^[2]^[why?]
the subclass $S^{+}(Y)$ for $Y\subseteq X$ are reachable with a sample that maps the elements of $X-Y$ to zero;^[2]^[why?]
the subclass $S(X)$ , which consists of the singleton sets, is not reachable.^[2]^[why?]

Applications[edit]

Let $C$ be some concept class. For any concept $c\in C$ , we call this concept $1/d$ -good for a positive integer $d$ if, for all $x\in X$ , at least $1/d$ of the concepts in $C$ agree with $c$ on the classification of $x$ .^[2] The fingerprint dimension $FD(C)$ of the entire concept class $C$ is the least positive integer $d$ such that every reachable subclass $C'\subseteq C$ contains a concept that is $1/d$ -good for it.^[2] This quantity can be used to bound the minimum number of equivalence queries^{[clarification needed]} needed to learn a class of concepts according to the following inequality: ${\textstyle FD(C)-1\leq \#EQ(C)\leq \lceil FD(C)\ln(|C|)\rceil }$ .^[2]