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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Discuss uniqueness of solution of $\Delta u -u\int_{\Omega}u^2(y)dy=f$

I'm trying to solve the following problem: Discuss the uniqueness of the following problems using energy methods: \begin{cases} \Delta u -u{\displaystyle \int_{\Omega}}u^2(y)dy=f \quad \mbox{in } \Omega\\ u=\varphi \quad \quad \quad \quad \quad…
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Show that if $u\in C^1(\mathbb{R}^2)$ solves $u_t + uu_x = 0$, then $u$ is constant

Let $u \in C^1(\mathbb{R}^2)$ be a solution to the first order equation $u_t + uu_x = 0$. Prove that $u$ is a constant function.
JZS
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Boundedness of Solutions to $p$-Laplace Equation

Suppose $B_1=\{x\in\mathbb{R}^n:\ \|x\|<1\}$, $N\geq 2$, $p\in (1,\infty)$, $u\in W^{1,p}_{loc}(B_1)$ satisfies $$\int_{B_1}|\nabla u|^{p-2}\nabla u\nabla\phi=\int_{B_1}f\phi,\ \forall\ \phi\in C_0^\infty(B_1) $$ where $f\in L^{q}(B_1)$,…
Tomás
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Wave Equations Concept questions

My Engineering Mathematics teacher have a very novel method of teaching. He thinks that while it's all good and well to learn the analytical side of math, he stresses more on the theory, than the application. Thus he gave us these questions that we…
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"Straightening Out the Boundary" in PDE

In Chapter 3 of Evans' PDE Text, we're interested in solving nonlinear first-order PDEs of the form $$F(Du, u, x) = 0 \text{ in } U \\ u = g \text{ on } \Gamma$$ In the section where constructing local solutions via the method of characteristics is…
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A fundamental solution for the Laplacian from a fundamental solution for the heat equation

Here is a heuristic reasoning. Suppose that the function $u(x, t)$ solves $$\partial_t u = \Delta u.$$ Integrating in $t$ we can define a new function $v$: $$v(x)=\int_0^\infty u(x, t)\, dt.$$ Applying the operator $-\Delta$ to $v$ we get…
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How to solve heat equation

Solve the Heat-Eqn. $$u_t=ku_{xx}$$ where $x,t>0$ and $u_x(0,t) =0$ and $u(x,0)=\begin{cases} 1, & 0 < x <2 \\ 0, & 2\leq x \end{cases} $ What are the solution methods? Separation of variables? Fourier Transform? I can' t solve…
HD239
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Uniqueness of solutions to parabolic PDEs with Neumann Boundary condition

Suppose the PDE $$u_t-\nabla(k((\vec{x})\nabla u)-q(\vec{x})u=F(\vec{x},t)\ \ ,\vec{x}\in\omega,\ \ \ t>0$$ with Neumann boundary condition $\nabla(\vec{x},t)\cdot\hat{n}=h(\vec{x},t), \ \ \ \vec{x}\in\partial\omega$. How do we prove that a solution…
vidyarthi
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Solving an inhomogeneous wave equation

I'm currently working on an exercise about an inhomogeneous wave equation (PDE) and I can't seem to figure it out completely. The equation is: $u_{tt}-u_{xx}=\cos{2t} $ With the boundary/initial conditions: $u(0,t)=u(1,t)=0 $ $u(x,0)=0 $ $u_t…
sds
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Using method of characteristics to solve transport equation

Question I am working on: Use the method of characteristics to find a solution for the generalized transport equation for $u(t,x)$ given by $$u_t+x^2u_x=0$$ for $x > 0$ and $t > 0$, with initial condition $u(0,x) = \cos(x)$ and subject to $u(t,0) =…
Peetrius
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Solve nonlinear equation $-xu_x+uu_y=y$

Solve nonlinear equation $$\left\{\begin{matrix} -xu_x+uu_y=y & \\ u(x,2x)=0& \end{matrix}\right.$$ using method of characteristic curves my attempt: for the pde we can write it as $\frac{dx}{-x}=\frac{dy}{u}=\frac{du}{y}$ but i cant solve…
user293581
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Hörmander's theorem on hypoelliptic PDEs - existence of solution?

I've seen many authors state that Hörmander theory implies the existence of a $C^\infty$ solution. For example, on Wikipedia it says: The great achievement of Hörmander's 1967 paper was to show that a smooth fundamental solution exists under a…
DoubleTrouble
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Radially symmetric solution to the wave equation in a 3+1 dimension using D'Alembert formula

I need help proving this equation which is a radially symmetric solution to the wave equation in a 3+1 dimension using D'Alembert formula. I am totally clueless as to how prove it. Thank you.
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Characteristic curves : Why do I get different results?

With a given $h(x)$ we want to solve $$xu_y-yu_x=u \\ u(x,0)=h(x)$$ I have solved it using two ways. $$$$ First way: For $x\neq 0$ we get $u_y-\frac{y}{x}u_x=\frac{u}{x}$. We have that $$\frac{du}{ds}=\frac{du}{dx}\cdot…
Mary Star
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Find by the method of characteristic, the integral surface which passes through the curve

Find by the method of characteristic, the integral surface of $$pq=xy$$ which passes through the curve $$z=x,y=0$$ By strip condition, there is a unique initial strip $$x_{0}=s,y_{0}=0,z_{0}=s,p_{0}=1,q_{0}=0$$ And the characteristic equations are…
Kavita
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