It's not clear what "applicative" is being used to mean without knowing the context.
If it's truly not referring to applicative functors (i.e.
Applicative), then it's probably referring to the form of application itself:
f a b c is an applicative form, and this is where applicative functors get their name from:
f <$> a <*> b <*> c is analogous. (Indeed, idiom brackets take this connection further, by letting you write it as
(| f a b c |).)
Similarly, "applicative languages" can be contrasted with languages that are not primarily based on the application of function to argument (usually in prefix form); concatenative ("stack based") languages aren't applicative, for instance.
To answer the question of why applicative functors are called what they are in depth, I recommend reading
Applicative programming with effects; the basic idea is that a lot of situations call for something like "enhanced application": applying pure functions within some effectful context. Compare these definitions of
map :: (a -> b) -> [a] -> [b]
map _  = 
map f (x:xs) = f x : map f xs
mapM :: (Monad m) => (a -> m b) -> [a] -> m [b]
mapM _  = return 
mapM f (x:xs) = do
x' <- f x
xs' <- mapM f xs
return (x' : xs')
mapA (usually called
mapA :: (Applicative f) => (a -> f b) -> [a] -> f [b]
mapA _  = pure 
mapA f (x:xs) = (:) <$> f x <*> mapA f xs
As you can see,
mapA is much more concise, and more obviously related to
map (even more so if you use the prefix form of
map too). Indeed, using the applicative functor notation even when you have a full
Monad is common in Haskell, since it's often much more clear.
Looking at the definition helps, too:
class (Functor f) => Applicative f where
pure :: a -> f a
(<*>) :: f (a -> b) -> f a -> f b
Compare the type of
(<*>) to the type of application:
($) :: (a -> b) -> a -> b. What
Applicative offers is a generalised "lifted" form of application, and code using it is written in an applicative style.
More formally, as mentioned in the paper and pointed out by ertes,
Applicative is a generalisation of the SK combinators;
pure is a generalisation of
K :: a -> (r -> a) (aka
(<*>) is a generalisation of
S :: (r -> a -> b) -> (r -> a) -> (r -> b). The
r -> a part is simply generalised to
f a; the original types are obtained with the
Applicative instance for
As a practical matter,
pure also allows you to write applicative expressions in a more uniform manner:
pure f <*> effectful <*> pure x <*> effectful as opposed to
(\a b -> f a x b) <$> effectful <*> effectful.