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System of imprimitivity

The concept of a system of imprimitivity is used in mathematics, particularly in algebra and analysis, both within the context of the theory of group representations. It was used by George Mackey as the basis for his theory of induced unitary representations of locally compact groups.

The simplest case, and the context in which the idea was first noticed, is that of finite groups (see primitive permutation group). Consider a group G and subgroups H and K, with K contained in H. Then the left cosets of H in G are each the union of left cosets of K. Not only that, but translation (on one side) by any element g of G respects this decomposition. The connection with induced representations is that the permutation representation on cosets is the special case of induced representation, in which a representation is induced from a trivial representation. The structure, combinatorial in this case, respected by translation shows that either K is a maximal subgroup of G, or there is a system of imprimitivity (roughly, a lack of full "mixing"). In order to generalise this to other cases, the concept is re-expressed: first in terms of functions on G constant on K-cosets, and then in terms of projection operators (for example the averaging over K-cosets of elements of the group algebra).


Mackey also used the idea for his explication of quantization theory based on preservation of relativity groups acting on configuration space. This generalized work of Eugene Wigner and others and is often considered to be one of the pioneering ideas in canonical quantization.

the elements of X are permuted by the action of G on subspaces and

H is the (internal) algebraic of the elements of X, i.e.,

direct sum

A strongly-continuous U: gUg of G on H.

unitary representation

A π on the Borel sets of X with values in the projections of H;

projection-valued measure

A horizontal line which intersects the y-axis at a non-zero value y0. In this case, we can take the quasi-invariant measure on this line to be Lebesgue measure.

A single point (x0,0) on the x-axis

G. W. Mackey, The Theory of Unitary Group Representations, University of Chicago Press, 1976.

V. S. Varadarajan, Geometry of Quantum Theory, Springer-Verlag, 1985.

David Edwards, The Mathematical Foundations of Quantum Mechanics, Synthese, Volume 42, Number 1/September, 1979, pp. 1–70.