In
mathematics, a Fréchet space is a
topological vector space which is almost a
Banach space, but
not quite. Fréchet spaces can arise as the
limit (in a
category theoretic sense, or less
formally) of a
sequence of
Banach spaces.
Suppose q is a quasi-norm on a vector space X (over the real or complex field). This means that
Then d(x, y) = q(x - y) defines a
metric on X, which makes X into a
metric space. The
metric d is
invariant under
translations: d(x + z, y + z) = d(x, y) for any x, y, z. If X is a
complete metric space in the
metric d induced by the quasi-
norm q, we say X is a Fréchet space.
In practice Fréchet spaces are most often constructed in the following way. Suppose {pj} is a countable family of seminorms on X. (This means that each pj obeys the triangle inequality, and unlike a quasi-norm respects multiplication by scalars, but pj may kill some points of X: there may be x ≠ 0 having pj(x) = 0.)
Suppose further that {pj} separates the points of X, in the sense that for any nonzero x in X, although many of the pj may satisfy pj(x) = 0, there is at least one pk with pk(x) ≠ 0. (Thus the pj taken all together are enough to distinguish every nonzero point of X from zero.) Then
q = ∑j≥1 pj / (2j (1 + pj))
defines a quasi-norm q on X. Then we may be able to prove that (X, q) is a complete quasi-normed vector space, thus that the seminorms pj make X into a Fréchet space. Defining it this way shows that a Fréchet space is precisely a locally convex space which is metrizable with a complete metric.
The simplest example of a Fréchet space which is not a Banach space is C∞(X), the space of infinitely differentiable functions on a compact smooth manifold X. C∞(X) is the intersection of the Banach spaces Ck(X) for k ∈ N. However, C∞(X) is not closed in Ck(X) for any finite k, so we cannot simply use any of the Banach space norms on Ck(X) to norm C∞(X); the resulting space is not complete. If instead we call each of the Ck norms a seminorm on C∞(X), and perform the construction above, the resulting space is complete, and thus a Fréchet space.
Banach spacers beware: the dual of a Fréchet space need not be a Fréchet space, and may be much worse. An example is Cc∞(X), the space of compactly supported smooth functions on X, whose dual is the space D′(X) of distributions on X, which is only an LF space, that is an inductive limit of Fréchet spaces.
For examples of the use of Fréchet spaces to perform functional analytic constructions where Banach space structure is absent, you might turn to Manifolds, tensor analysis and applications by Abraham, Marsden and Ratiu, or to volumes 2, 7 and 8 of the amazing Treatise on analysis by Jean Dieudonné. For more abstract information on topological vector spaces of all kinds consult Topological vector spaces by H. H. Schaefer, in the Springer GTM series.