Solution of a class of Volterra integral equations with singular and weakly singular kernels. (English) Zbl 1148.45002
The purpose of the paper is to derive the solution to a Volterra integral equation
\[
y(t)=g(t)+\int^t_0\frac{s^{\mu-\nu}}{t^\mu}y(s)\,ds\quad (0<t<T),
\]
where \(\mu\) and \(\nu\) are constants, and \(g(t)\) a given function. Set \[ \varphi(t)=\int^t_0{s^{\mu-\nu}}y(s)\,ds \quad (0<t<T). \]
Then the Volterra integral equation is transformed into a first-order ordinary differential equation
\[ t^\nu\frac{d\varphi}{dt}=t^\mu g(t)+\varphi(t)\quad (0<t<T). \]
Based on such a transformation, the authors derive analytically a general solution to the Volterra integral equation.
where \(\mu\) and \(\nu\) are constants, and \(g(t)\) a given function. Set \[ \varphi(t)=\int^t_0{s^{\mu-\nu}}y(s)\,ds \quad (0<t<T). \]
Then the Volterra integral equation is transformed into a first-order ordinary differential equation
\[ t^\nu\frac{d\varphi}{dt}=t^\mu g(t)+\varphi(t)\quad (0<t<T). \]
Based on such a transformation, the authors derive analytically a general solution to the Volterra integral equation.
Reviewer: Jin Liang (Shanghai)
MSC:
| 45E10 | Integral equations of the convolution type (Abel, Picard, Toeplitz and Wiener-Hopf type) |
Keywords:
Volterra integral equation; singular kernel; ordinary differential equation; analytic solutionReferences:
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