Questions tagged [partial-differential-equations]

Questions on partial (as opposed to ordinary) differential equations - equations involving partial derivatives of one or more dependent variables with respect to more than one independent variables.

Partial differential equations (PDEs) contain partial derivatives and usually contain two or more variables; the single-variable cases with normal derivatives are ordinary differential equations.

In general partial differential equation can be written in the form $$f(x, y, ,\dots , u, u_x, u_y, \dots , u_{xx}, u_{xy}, \dots )=0$$involving several independent variables $x, y, \dots ,$ an unknown function $u$ of these variables, and the partial derivatives $u_x, u_y, \dots, u_{xx}, u_{xy}, \dots$, of the function.

Subscripts on dependent variables denote differentiations, e.g., $$u_x\equiv \frac{\partial u}{\partial x},\quad u_{xy}\equiv \frac{\partial^2 u}{\partial x \partial y },$$and so on. The $f$ denotes a function defined on a subset of a finite dimensional space. Functional operators on functions like $f(u):=\frac{du}{dx}$ are not allowed in this definition. For instance, Laplace's equation in three dimensions $u_{xx} + u_{yy} + u_{zz} = 0$ is defined by $f(x,y,z,\nabla u,\nabla^2 u) = 0$, where $$f(a,b,c,v,M) := M_{11} + M_{22} + M_{33}.$$

Questions with this tag may be about, among other things:

  1. Analysis of existence and uniqueness of classical/strong/weak/viscous/etc. solutions in boundary value problems/Cauchy problems/Riemann problems.
  2. Functional analysis related to PDEs, e.g., theories of Sobolev spaces, Bochner spaces, analysis of linear/nonlinear differential operators, and pseudodifferential operators, etc.
  3. The stability, or long-term behavior of the solution.
  4. Different methods of solving PDEs, separation of variables, Fourier transform, solitons, method of characteristics.
  5. The solution technique of the Euler-Lagrange equations from calculus of variations.
  6. Equation-relevant theory in other fields, e.g. Hyperbolic conservation laws in fluid/gas dynamics, Maxwell's equations in electromagnetism, Hamilton-Jacobi equation in control theory, etc.

Please consider using more specific tags if your question addresses some of the aspects in that field, e.g., , , , , , , , .

References:

"Partial Differential Equations" by L. C. Evans

" Linear Partial. Differential Equations for Scientists and Engineers" by Tyn Myint-U & Lokenath Debnath

"Differential Equations" by Shepley L. Ross

See also the Wikipedia and MathWorld entries.

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Doubt on solution of PDE

To Solve: $\displaystyle (x^2-y^2-z^2)\frac{\partial z}{\partial x}+2xy\frac{\partial z}{\partial y}=2xz$ Subsidiary equation: $\displaystyle \frac{dx}{x^2-y^2-z^2}=\frac{dy}{2xy}=\frac{dz}{2xz}$ Using multipliers x,y and z, we have each…
square_one
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To Solve a linear PDE of first order

To Solve: $\displaystyle \cos(x+y)\frac{\partial z}{\partial x}+\sin(x+y)\frac{\partial z}{\partial y}=z$ My attempt: Forming the subsidiary equations: $\displaystyle \frac{dx}{\cos(x+y)}=\frac{dy}{\sin(x+y)}=\frac{dz}{z}$ I was hoping to use the…
square_one
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To Solve a PDE by direct integration

$\displaystyle \frac{\partial^2 z}{\partial x^2}=a^2z $, given that when $\displaystyle x=0, \frac{\partial z}{\partial x}=a\sin y$ and $\displaystyle \frac{\partial z}{\partial y}=0 $ The solution is given as $\displaystyle z=\sin x+ e^y\cos x$.…
square_one
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Example of non-local operator

Let $T: C_{0}^{\infty}(R^{n}) \to C^{\infty}(R^{n})$ be a linear operator. $T$ is local if $$\operatorname{supp} (Tu) \subset \operatorname{supp} (u),$$ for all $u \in C_{0}^{\infty}({R}^{n})$. We know all differential operators are local. But what…
curiousm
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Solving a linear PDE

Page 99 of PDE Evans, 2nd edition, says In summary, \begin{cases} \tag{17} \dot{\textbf{x}}(s)=\textbf{b}(\textbf{x}(s)) \\ \dot{z}(s) = -c(\textbf{x}(s))z(s)\end{cases}will comprise the characteristic equations for the linear, first-order PDE…
Cookie
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Solve the cauchy problem and check the solution?

Consider $$xU_x +y U_y = 0$$ $$U(x,y) = x, \ \ \ \ on \ \ \ \ x^2 + y^2 = 1$$ has a solution for all x,y $\in \mathbb R$ an unique solution in $\{ (x,y) \in \mathbb R^2 : (x,y) \neq 0 \}$ a bounded solution in $\{ (x,y) \in \mathbb R^2 : (x,y)…
Struggler
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Why does envelope solve Hamilton-Jacobi equation?

Consider the initial value problem $$\partial_t u+ H(Du)=0 \, \, \mbox{in $\mathbb{R}^n \times \mathbb{R}_{>0}$}$$ $$ u(0, x)=g(x) \, \, \mbox{on $\mathbb{R}^n \times 0$}$$ where $H$ is smooth, convex and coercive and $g$ is Lipschitz. Can you tell…
phil
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Min-Max Principle and Harnack's inequality

I read a statement online that Harnack's inequality is a more accurate and quantitative version of the Maximum principle. But it seems that it's impossible to deduce the maximum principle from Harnack's inequality. The difficulties (among a few…
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PDE Characteristic Equations - Remembering Them?

Is there a quick smart intuitive way to see that $$\frac{dx}{F_p} = \frac{dy}{F_q} = \frac{du}{pF_p+qF_q} = - \frac{dp}{F_x+pF_u} = - \frac{dp}{F_y+qF_u}$$ are the characteristic equations for a non-linear pde $F(x,y,u,u_x,u_y)= 0$? Doesn't even…
bolbteppa
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Green's Function Solutions

So, I'm considering a PDE and trying to find its Green's function first. To this end, I solve the following helmholtz equation: $$\frac{d^2g}{dx^2}+\frac{d^2g}{dy^2}+\frac{d^2g}{dz^2}-\alpha^2g=\delta(x-\xi)\delta{(y-\eta)}\delta{(z-\rho)}$$ Well,…
Incognito
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PDE models in life and social sciences

I wanted to know if there are models based on diffusion-convection PDEs in the social sciences, life-sciences, health & public policy, etc. I would assume that phenomena like the spread of diseases/species/populations/genes/memes, transport of…
firdaus
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How can this IBVP with regularity boundary conditions be solved?

I have a radial Schrödinger equation for a particle in Coulomb potential: $$i\partial_t f(r,t)=-\frac1{r^2}\partial_r\left(r^2\partial_r f(r,t)\right)-\frac2rf(r,t)$$ with initial condition $$f(r,0)=e^{-r^2}$$ and boundary…
Ruslan
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Solving Cauchy problem

I'm trying to solve the Cauchy problem \begin{align*} u_{xx} + u_{yy} =0 \\ u(x,0) = x^2, u_y(x,0) = e^x \end{align*} for a solution near (0,0). So far, I reduce the problem to an equivalent first order Cauchy problem, but I feel that it is harder…
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$u$ vanishes identically in unit ball

Let $B_1$ be the unit open ball in $\Bbb R^n$ centered at zero and let $a_i(x_1,... x_n), i =1,... n$ be continuous functions on $\bar B_1$. Suppose$\sum_1^n a_i(x_1,... x_n)x_i <0$ on $\partial B_1$,the boundary of $B_1$. Assume that $u$ is a $C^1$…
Toeplitz
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Ladyzhenskaya's inequality

I know a version of Ladyzhenskaya's inequality, that is Let $\Omega$ be bounded domain in $\mathbb R^2$, we have $$\|u\|^2_{L^4} \leq C\|u\|_{L^2}\|\nabla u\|_{L^2}, \quad \forall u\in H^1(\Omega).$$ So is it true when $\Omega$ is unbounded? And…
BTTD
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