A global theory of algebras of generalized functions
Abstract
We present a geometric approach to defining an algebra G(M) (the Colombeau algebra) of generalized functions on a smooth manifold M containing the space D'(M) of distributions on M. Based on differential calculus in convenient vector spaces we achieve an intrinsic construction of G(M). G(M) is a differential algebra, its elements possessing Lie derivatives with respect to arbitrary smooth vector fields. Moreover, we construct a canonical linear embedding of D'(M) into G(M) that renders C∞ (M) a faithful subalgebra of G(M). Finally, it is shown that this embedding commutes with Lie derivatives. Thus G(M) retains all the distinguishing properties of the local theory in a global context.
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