Revisions to Existence of solution to nonlinear first order PDE with C^1 bounds

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edited Feb 3 at 8:22

Daniele Tampieri

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I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$$$|F(f) - F(g)| \leq K \|f(\cdot, t) - g(\cdot, t)\|_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ $$ |F(f) - F(g)| \leq K \|f(\cdot, t) - g(\cdot, t)\|_{C^k(U)} $$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $(\Delta - 1) u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a(a smooth convex set with boundary) and $u \Big|_{\partial \Omega} = F(\nabla^2 f, \nabla f)$$u \big|_{\partial \Omega} = F(\nabla^2 f, \nabla f)$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $(\Delta - 1) u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = F(\nabla^2 f, \nabla f)$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K \|f(\cdot, t) - g(\cdot, t)\|_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $$ |F(f) - F(g)| \leq K \|f(\cdot, t) - g(\cdot, t)\|_{C^k(U)} $$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $(\Delta - 1) u = 0$ on $\Omega \subseteq \mathbb{R}^n$ (a smooth convex set with boundary) and $u \big|_{\partial \Omega} = F(\nabla^2 f, \nabla f)$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

Changed example

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edited Feb 2 at 17:49

JMK

337
2
11

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $\Delta u = 0$$(\Delta - 1) u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = f$$u \Big|_{\partial \Omega} = F(\nabla^2 f, \nabla f)$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $\Delta u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = f$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $(\Delta - 1) u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = F(\nabla^2 f, \nabla f)$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

added 46 characters in body

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edited Feb 1 at 23:54

JMK

337
2
11

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f - g||_{C^1}$$$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f - g||_{C^k}$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $\Delta u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = f$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f - g||_{C^1}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f - g||_{C^k}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $\Delta u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = f$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

I'm looking for general existence of a PDE of the form

$$ f: U \times [0, \delta) \to \mathbb{R}$$

$$\frac{\partial f}{\partial t}(p,t) = F(f(p,t))$$

where $f(p,0)$ is prescribed and $F$ is non-linear but it is known that

$$|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^1(U)}$$

I'm interested in how one would prove short time existence, and also if I can allow for $|F(f) - F(g)| \leq K ||f(\cdot, t) - g(\cdot, t)||_{C^k(U)}$ with $k \geq 2$ and still get the same existence. I'm struggling to find analogies to previous existence theorems, e.g. those for parabolic systems or using Picard-iterates (which would require a different lipschitz bound)

My PDE is similar in spirit to the following: solve $\Delta u = 0$ on $\Omega \subseteq \mathbb{R}^n$ a smooth convex set with boundary and $u \Big|_{\partial \Omega} = f$ with $f: \partial \Omega \to \mathbb{R}$. Then

$$\frac{\partial f}{\partial t}(p) = \frac{\partial u}{\partial \nu}(p) $$

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asked Feb 1 at 22:44

JMK

337
2
11

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