Functional integration: Difference between revisions

In an ordinary integral (in the sense of [[Lebesgue integration]]) there is a function to be integrated (the integrand) and a region of space over which to integrate the function (the ___domain of integration). The process of integration consists of adding up the values of the integrand for each point of the ___domain of integration. Making this procedure rigorous requires a limiting procedure, where the ___domain of integration is divided into smaller and smaller regions. For each small region, the value of the integrand cannot vary much, so it may be replaced by a single value. In a functional integral the ___domain of integration is a space of functions. For each function, the integrand returns a value to add up. Making this procedure rigorous poses challenges that continue to be topics of current research. [Note on this introduction: While the main rigorous mathematical complications/issues with Functional/Feynman integral is directly linked to measure theory, instead of starting with Lebesgue integral, starting with Riemann integral (or even Newton /Leibnitz integral) would make this introduction far more accessible to wider audience before we go into topics like measure theory including Lebesgue integral, and functional space. Is anyone with a great communication skills willing to write up a comprehensive introduction that is accessible to 1st or 2nd year undergraduates in pure mathematics/mathematical physics or theoretical physics/physics?]

Functional integration is central to quantization techniques in theoretical physics. The algebraic properties of functional integrals are used to develop series used to calculate properties in [[quantum electrodynamics]] and the [[standardStandard modelModel]] of particle physics.