Difference between revisions of "Strong solution"
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''of a differential equation'' | ''of a differential equation'' | ||
− | $$Lu\equiv\sum_{|\alpha|\leq m}a_\alpha(x)D^\alpha u=f\tag{*}$$ | + | $$Lu\equiv\sum_{|\alpha|\leq m}a_\alpha(x)D^\alpha u=f\label{*}\tag{*}$$ |
''in a domain $D$'' | ''in a domain $D$'' | ||
− | A locally integrable function $u$ that has locally integrable generalized derivatives of all orders $\leq m$ (cf. [[Generalized derivative|Generalized derivative]]), and satisfies \ | + | A locally integrable function $u$ that has locally integrable generalized derivatives of all orders $\leq m$ (cf. [[Generalized derivative|Generalized derivative]]), and satisfies \eqref{*} almost-everywhere in $D$. |
− | The notion of a "strong solution" can also be introduced as follows. A function $u$ is called a strong solution of \ | + | The notion of a "strong solution" can also be introduced as follows. A function $u$ is called a strong solution of \eqref{*} if there are sequences of smooth (for example, $C^\infty$) functions $\{u_n\}$, $\{f_n\}$ such that $u_n\to u$, $f_n\to f$ and $Lu_n=f_n$ for each $n$, where the convergence is taken in $L_1(K)$ for any compact set $K\subseteq D$. In these definitions, $L_1$ can be replaced by the class $L_p$ of functions whose $p$-th powers are locally integrable. The class most often used is $L_2$. |
− | In the case of an elliptic equation \ | + | In the case of an elliptic equation \eqref{*} both notions of a strong solution coincide. |
Latest revision as of 15:58, 14 February 2020
of a differential equation
$$Lu\equiv\sum_{|\alpha|\leq m}a_\alpha(x)D^\alpha u=f\label{*}\tag{*}$$
in a domain $D$
A locally integrable function $u$ that has locally integrable generalized derivatives of all orders $\leq m$ (cf. Generalized derivative), and satisfies \eqref{*} almost-everywhere in $D$.
The notion of a "strong solution" can also be introduced as follows. A function $u$ is called a strong solution of \eqref{*} if there are sequences of smooth (for example, $C^\infty$) functions $\{u_n\}$, $\{f_n\}$ such that $u_n\to u$, $f_n\to f$ and $Lu_n=f_n$ for each $n$, where the convergence is taken in $L_1(K)$ for any compact set $K\subseteq D$. In these definitions, $L_1$ can be replaced by the class $L_p$ of functions whose $p$-th powers are locally integrable. The class most often used is $L_2$.
In the case of an elliptic equation \eqref{*} both notions of a strong solution coincide.
Comments
References
[a1] | J. Chazarain, A. Piriou, "Introduction à la théorie des équations aux dérivées partielles linéaires" , Gauthier-Villars (1981) pp. 223 MR0598467 Zbl 0446.35001 |
Strong solution. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Strong_solution&oldid=32910