Denote the input of a system by ${\displaystyle h(t)}$  (e.g. a force), and the response of the system by ${\displaystyle x(t)}$  (e.g. a position). Generally, the value of ${\displaystyle x(t)}$  will depend not only on the present value of ${\displaystyle h(t)}$ , but also on past values. Approximately ${\displaystyle x(t)}$  is a weighted sum of the previous values of ${\displaystyle h(t')}$ , with the weights given by the linear response function ${\displaystyle \chi (t-t')}$ :

The explicit term on the right-hand side is the leading order term of a Volterra expansion for the full nonlinear response. If the system in question is highly non-linear, higher order terms in the expansion, denoted by the dots, become important and the signal transducer cannot adequately be described just by its linear response function.

The complex-valued Fourier transform ${\displaystyle {\tilde {\chi }}(\omega )}$  of the linear response function is very useful as it describes the output of the system if the input is a sine wave ${\displaystyle h(t)=h_{0}\sin(\omega t)}$  with frequency ${\displaystyle \omega }$ . The output reads

with amplitude gain ${\displaystyle |{\tilde {\chi }}(\omega )|}$  and phase shift ${\displaystyle \arg {\tilde {\chi }}(\omega )}$ .

Consider a damped harmonic oscillator with input given by an external driving force ${\displaystyle h(t)}$ ,

The complex-valued Fourier transform of the linear response function is given by

The amplitude gain is given by the magnitude of the complex number ${\displaystyle {\tilde {\chi }}(\omega ),}$  and the phase shift by the arctan of the imaginary part of the function divided by the real one.

From this representation, we see that for small ${\displaystyle \gamma }$  the Fourier transform ${\displaystyle {\tilde {\chi }}(\omega )}$  of the linear response function yields a pronounced maximum ("Resonance") at the frequency ${\displaystyle \omega \approx \omega _{0}}$ . The linear response function for a harmonic oscillator is mathematically identical to that of an RLC circuit. The width of the maximum, ${\displaystyle \Delta \omega ,}$  typically is much smaller than ${\displaystyle \omega _{0},}$  so that the Quality factor ${\displaystyle Q:=\omega _{0}/\Delta \omega }$  can be extremely large.

The exposition of linear response theory, in the context of quantum statistics, can be found in a paper by Ryogo Kubo.^[1] This defines particularly the Kubo formula, which considers the general case that the "force" h(t) is a perturbation of the basic operator of the system, the Hamiltonian, ${\displaystyle {\hat {H}}_{0}\to {\hat {H}}_{0}-h(t'){\hat {B}}(t')}$  where ${\displaystyle {\hat {B}}}$  corresponds to a measurable quantity as input, while the output x(t) is the perturbation of the thermal expectation of another measurable quantity ${\displaystyle {\hat {A}}(t)}$ . The Kubo formula then defines the quantum-statistical calculation of the susceptibility ${\displaystyle \chi (t-t')}$  by a general formula involving only the mentioned operators.

As a consequence of the principle of causality the complex-valued function ${\displaystyle {\tilde {\chi }}(\omega )}$  has poles only in the lower half-plane. This leads to the Kramers–Kronig relations, which relates the real and the imaginary parts of ${\displaystyle {\tilde {\chi }}(\omega )}$  by integration. The simplest example is once more the damped harmonic oscillator.^[2]

• Convolution
• Green–Kubo relations
• Fluctuation theorem
• Dispersion (optics)
• Lindblad equation
• Semilinear response
• Green's function
• Impulse response
• Resolvent formalism
• Propagator

• in Eva Pavarini, Erik Koch, Dieter Vollhardt, and Alexander Lichtenstein (eds.): DMFT at 25: Infinite Dimensions, Verlag des Forschungszentrum Jülich, 2014 ISBN 978-3-89336-953-9