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YCor
YCor
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Regularization property after Transporttransport

I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally LiepschitzLipschitz. Moreover, let's suppose that its flow $\Phi^X_t$ is space-smooth at $t=1$.

Now let's modify $X$ through another locally LiepschitzLipschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is space-smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.

Regularization property after Transport

I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally Liepschitz. Moreover, let's suppose that its flow $\Phi^X_t$ is space-smooth at $t=1$.

Now let's modify $X$ through another locally Liepschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is space-smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.

Regularization property after transport

I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally Lipschitz. Moreover, let's suppose that its flow $\Phi^X_t$ is space-smooth at $t=1$.

Now let's modify $X$ through another locally Lipschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is space-smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.

deleted 6 characters in body
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Mirko
Mirko
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I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally Liepschitz. Moreover, let's suppose that its flow $\Phi^X_t$ exist is space-smooth at $t=1$.

Now let's modify $X$ through another locally Liepschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is smoothspace-smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.

I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally Liepschitz. Moreover, let's suppose that its flow $\Phi^X_t$ exist is space-smooth at $t=1$.

Now let's modify $X$ through another locally Liepschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.

I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally Liepschitz. Moreover, let's suppose that its flow $\Phi^X_t$ is space-smooth at $t=1$.

Now let's modify $X$ through another locally Liepschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is space-smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.

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Mirko
Mirko
  • 147
  • 6

Regularization property after Transport

I have the following question:

let's suppose we have some continous vector field $X$ on a compact surface and let's suppose that it is locally Liepschitz. Moreover, let's suppose that its flow $\Phi^X_t$ exist is space-smooth at $t=1$.

Now let's modify $X$ through another locally Liepschitz vector field $Y$: we define a new field $T_t$ through the transport equation $$\frac{d}{dt} T_t = \mathcal{L}_Y T_t, \quad T_0 = X$$

Let's suppose that also $Y$ has the property that $\Phi_t^Y$ is space-smooth at $t = 1$. Is it true that the flow of $T_t$ is smooth for $t = 1$?

My knowledge is very basic, I'm a geometer. I need the previous fact in order to construct an isotopy on some manifold.