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reseacher
reseacher
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Consider the linear wave equation :

$$z_{tt}=\Delta z + k(x) z + h(t) , \; in \; \Omega\times (0,T)$$

Are there sufficient conditions on the functions $k(x)$ and $h(t)$ for which $(y,y_t)$$(z,z_t)$ vanish at $T$, i.e $y(T)=y_t(T)=0$$z(T)=z_t(T)=0$.

Thanks!

Consider the linear wave equation :

$$z_{tt}=\Delta z + k(x) z + h(t) , \; in \; \Omega\times (0,T)$$

Are there sufficient conditions on the functions $k(x)$ and $h(t)$ for which $(y,y_t)$ vanish at $T$, i.e $y(T)=y_t(T)=0$.

Thanks!

Consider the linear wave equation :

$$z_{tt}=\Delta z + k(x) z + h(t) , \; in \; \Omega\times (0,T)$$

Are there sufficient conditions on the functions $k(x)$ and $h(t)$ for which $(z,z_t)$ vanish at $T$, i.e $z(T)=z_t(T)=0$.

Thanks!

Source Link
reseacher
reseacher
  • 51
  • 3

null controllability of linear wave equation

Consider the linear wave equation :

$$z_{tt}=\Delta z + k(x) z + h(t) , \; in \; \Omega\times (0,T)$$

Are there sufficient conditions on the functions $k(x)$ and $h(t)$ for which $(y,y_t)$ vanish at $T$, i.e $y(T)=y_t(T)=0$.

Thanks!