Integro-differential equation

The general first-order, linear (only with respect to the term involving derivative) integro-differential equation is of the form

:$$

\frac{d}{dx}u(x) + \int_{x_0}^x f(t,u(t))\,dt = g(x,u(x)), \qquad u(x_0) = u_0, \qquad x_0 \ge 0.

As is typical with differential equations, obtaining a closed-form solution can often be difficult. In the relatively few cases where a solution can be found, it is often by some kind of integral transform, where the problem is first transformed into an algebraic setting. In such situations, the solution of the problem may be derived by applying the inverse transform to the solution of this algebraic equation.

Consider the following second-order problem,

: $$

u'(x) + 2u(x) + 5\int_{0}^{x}u(t)\,dt = \theta(x)

\qquad \text{with} \qquad u(0)=0,

where

: $$

\theta(x) = \left\{ \begin{array}{ll}

1, \qquad x \geq 0\\

0, \qquad x < 0 \end{array}

\right.

is the Heaviside step function. The Laplace transform is defined by,

:$U(s)\; =\; \backslash mathcal\{L\}\; \backslash left\backslash \{u(x)\backslash right\backslash \}=\backslash int\_0^\{\backslash infty\}\; e^\{-sx\}\; u(x)\; \backslash ,dx.$

Upon taking term-by-term Laplace transforms, and utilising the rules for derivatives and integrals, the integro-differential equation is converted into the following algebraic equation,

:$s\; U(s)\; -\; u(0)\; +\; 2U(s)\; +\; \backslash frac\{5\}\{s\}U(s)\; =\; \backslash frac\{1\}\{s\}.$

Thus,

:$U(s)\; =\; \backslash frac\{1\}\{s^2\; +\; 2s\; +\; 5\}$.

Inverting the Laplace transform using contour integral methods then gives

:$u(x)\; =\; \backslash frac\{1\}\{2\}\; e^\{-x\}\; \backslash sin(2x)\; \backslash theta(x)$.

Alternatively, one can complete the square and use a table of Laplace transforms ("exponentially decaying sine wave") or recall from memory to proceed:

:$U(s)\; =\; \backslash frac\{1\}\{s^2\; +\; 2s\; +\; 5\}\; =\; \backslash frac\{1\}\{2\}\; \backslash frac\{2\}\{(s+1)^2+4\}\; \backslash Rightarrow\; u(x)\; =\; \backslash mathcal\; L^\{-1\}\backslash left\backslash \{\; U(s)\; \backslash right\backslash \}\; =\; \backslash frac\{1\}\{2\}\; e^\{-x\}\; \backslash sin(2x)\; \backslash theta(x)$.

Integro-differential equations model many situations from science and engineering, such as in circuit analysis. By Kirchhoff's second law, the net voltage drop across a closed loop equals the voltage impressed $E(t)$. (It is essentially an application of energy conservation.) An RLC circuit therefore obeys

$$L\; \backslash frac\{d\}\{dt\}I(t)\; +\; RI(t)\; +\; \backslash frac\{1\}\{C\}\; \backslash int\_\{0\}^\{t\}\; I(\backslash tau)\; d\backslash tau\; =\; E(t),$$

where $I(t)$ is the current as a function of time, $R$ is the resistance, $L$ the inductance, and $C$ the capacitance.Zill, Dennis G., and Warren S. Wright. “Section 7.4: Operational Properties II.” [https://books.google.com/books?id=0UX8e0xdOr0C&q=Integrodifferential Differential Equations with Boundary-Value Problems], 8th ed., Brooks/Cole Cengage Learning, 2013, p. 305. {{ISBN|978-1-111-82706-9}}. Chapter 7 concerns the Laplace transform.

The activity of interacting inhibitory and excitatory neurons can be described by a system of integro-differential equations, see for example the Wilson-Cowan model.

The Whitham equation is used to model nonlinear dispersive waves in fluid dynamics.{{Cite book |last=Whitham |first=G.B. |title=Linear and Nonlinear Waves |publisher=Wiley |year=1974 |location=New York |isbn=0-471-94090-9 }}

Integro-differential equations have found applications in epidemiology, the mathematical modeling of epidemics, particularly when the models contain age-structure{{Cite book|date=2008|editor-last=Brauer|editor-first=Fred|editor2-last=van den Driessche|editor2-first=Pauline|editor2-link=Pauline van den Driessche|editor3-last=Wu|editor3-first=Jianhong|title=Mathematical Epidemiology|series=Lecture Notes in Mathematics|volume=1945|pages=205–227|doi=10.1007/978-3-540-78911-6|isbn=978-3-540-78910-9|issn=0075-8434}} or describe spatial epidemics.{{Cite web|url=http://people.oregonstate.edu/~medlockj/other/IDE.pdf|title=Integro-differential-Equation Models for Infectious Disease|last=Medlock|first=Jan|date=March 16, 2005|website=Yale University|archive-url=https://web.archive.org/web/20200321190642/http://people.oregonstate.edu/~medlockj/other/IDE.pdf|archive-date=2020-03-21}} The Kermack-McKendrick theory of infectious disease transmission is one particular example where age-structure in the population is incorporated into the modeling framework.

• Delay differential equation
• Differential equation
• Integral equation
• Integrodifference equation

{{Reflist}}

• Vangipuram Lakshmikantham, M. Rama Mohana Rao, “[https://books.google.com/books?id=p1ZLP4OHp4YC&dq=%22Theory+of+Integro-Differential+Equations%22&pg=PR9 Theory of Integro-Differential Equations]”, CRC Press, 1995

• [http://www.intmath.com/Laplace-transformation/9_Integro-differential-eqns-simultaneous-DE.php Interactive Mathematics]
• [http://www.chebfun.org/examples/integro/WikiIntegroDiff.html Numerical solution] of the example using Chebfun

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Category:Differential equations