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Line 1: In [[mathematics]], the '''scale convolution''' of two [[Function (mathematics)\|functions]] <math>s(t)</math> and <math>r(t)</math>, also known as their '''logarithmic convolution''' or '''log-volution'''<ref>{{Cite book\|title= An Introduction to Exotic Option Pricing \| series = Chapman and Hall/CRC Financial Mathematics Series \| author = Peter Buchen \| publisher = CRC Press\| date = 2012 \| ISBN = 9781420091021}}</ref> is defined as the function<ref name=pm>{{Cite web\|url=https://planetmath.org/logarithmicconvolution\|work=Planet Math\| title = logarithmic convolution \|date=22 March 2013\|access-date=15 September 2024}}</ref> ~~{{unreferenced\|date=October 2010}}~~ ~~The '''scale convolution''' of two functions <math>s(t)</math> and <math>r(t)</math>, also known as their '''logarithmic convolution''' is defined as the function<br>dodo~~ :<math> s _l r(t) = r _l s(t) = \int_0^\infty s\left(\frac{t}{a}\right)r(a) \, \frac{da}{a}</math>▼ when this quantity exists.▼ ==Results==▼ The logarithmic convolution can be related to the ordinary [[convolution]] by changing the [[Variable (mathematics)\|variable]] from <math>t</math> to <math>v = \log t</math>:<ref name=pm />▼ : <math>\begin{align} ▲:<math> s _l r(t) = r _l s(t) = \int_0^\infty s\left(\frac{t}{a}\right)r(a) \frac{da}{a}</math> ~~: <math>~~ s _l r(t) & = \int_0^\infty s \left(\frac{t}{a}\right)r(a) \, \frac{da}{a} =\\▼ & = \int_{-\infty}^\infty s\left(\frac{t}{e^u}\right) r(e^u) \, du ~~</math>~~\\▼ ~~:<math>~~& = \int_{-\infty}^\infty s \left(e^{\log t - u}\right)r(e^u) \, du.~~</math>~~▼ \end{align}</math> Define <math>f(v) = s(e^v)</math> and <math>g(v) = r(e^v)</math> and let <math>v = \log t</math>, then▼ ▲when this quantity exists. :<math> s _l r(v) = f * g(v) = g * f(v) = r _l s(v).\, </math>▼ ▲==Results== ▲The logarithmic convolution can be related to the ordinary convolution by changing the variable from <math>t</math> to <math>v = \log t</math>: ==See also== ▲: <math> s _l r(t) = \int_0^\infty s\left(\frac{t}{a}\right)r(a) \frac{da}{a} = * [[Mellin transform]] ▲\int_{-\infty}^\infty s\left(\frac{t}{e^u}\right) r(e^u) du </math> ==References== ▲:<math> = \int_{-\infty}^\infty s\left(e^{\log t - u}\right)r(e^u) du.</math> {{Reflist}} ==External links== ▲Define <math>f(v) = s(e^v)</math> and <math>g(v) = r(e^v)</math> and let <math>v = \log t</math>, then {{PlanetMath attribution\|id=5995\|title=logarithmic convolution\|access-date=12 August 2006}} ▼ {{Authority control}} ▲:<math> s _l r(v) = f g(v) = g * f(v) = r *_l s(v).\, </math> {{Use dmy dates\|date=September 2024}} ▲{{PlanetMath attribution\|id=5995\|title=logarithmic convolution}} [[Category:Logarithms]]