When stating that `A`

is a *subclass of* `B`

, this restricts `A`

to necessarily inherit all characteristics of `B`

, **but not the other way around**. In your example, `A`

= `Teenager`

, and `B`

= `hasAge [12:19]`

(my own notation, but you get the idea).

This means that any instance of `Teenager`

in the OWL ontology must necessarily also have the property `hasAge`

with a value in the range `[12:19]`

, but *not* the other way around. Specifically, this does not mean that any instance of something with the property `hasAge`

with a value in the range `[12:19]`

is also an instance of `Teenager`

. To make this clear, consider an instance (called `c`

) of class `Car`

. We might also say that:

`c . hasAge 13`

This says that instance `c`

of `Car`

is 13 years old. However, with the subclass axiom defining `Teenager`

above, a **reasoner** would **not** infer that `c`

is also an instance of `Teenager`

(perhaps as we'd want, if teenagers are *people*, not cars).

The difference when using equivalence is that the subclass relationship is implied to go in **both directions**. So, if we were to instead include the second axiom that defined `Teenager`

to be *equivalent* to anything with the property `hasAge`

with a value in the range `[12:19]`

, then a reasoner would infer that the car `c`

is also an instance of `Teenager`

.