Explain why the area of $S$ is equal to $int_C x,dsigma$ ( line integral )
Let $S$ be a surface in $mathbb{R^3}
$ with the parametrization $g(s, t) = (t, t^2
, st)$
where $g : [0, 1] × [0, 10] → mathbb{R^3}
$
. Explain why the area of $S$ is equal
to $int_C xdσ$
, where $C$ is the curve in $mathbb{R^2}$
parameterized by $h(t) = (t, t^2
)$,
$h : [0, 10] → mathbb{R^2}$
and Find the area of $S$.
i didn't understand the question at all how can i explain that . Area $S$ =
$int_C x,dsigma$ .
i know that the surface area is given by :
$ int f(x(t),y(t)|r'(t)| { dt}$
but the curve siting in the $[xy]$ plane is $h(t)$ so my guess (might be wrong) that $|r'(t)|$ = $sqrt{4t^2 + 1}$ and $f(x(t),y(t)) = st = sx$ .
integration multivariable-calculus curvature line-integrals
add a comment |
Let $S$ be a surface in $mathbb{R^3}
$ with the parametrization $g(s, t) = (t, t^2
, st)$
where $g : [0, 1] × [0, 10] → mathbb{R^3}
$
. Explain why the area of $S$ is equal
to $int_C xdσ$
, where $C$ is the curve in $mathbb{R^2}$
parameterized by $h(t) = (t, t^2
)$,
$h : [0, 10] → mathbb{R^2}$
and Find the area of $S$.
i didn't understand the question at all how can i explain that . Area $S$ =
$int_C x,dsigma$ .
i know that the surface area is given by :
$ int f(x(t),y(t)|r'(t)| { dt}$
but the curve siting in the $[xy]$ plane is $h(t)$ so my guess (might be wrong) that $|r'(t)|$ = $sqrt{4t^2 + 1}$ and $f(x(t),y(t)) = st = sx$ .
integration multivariable-calculus curvature line-integrals
add a comment |
Let $S$ be a surface in $mathbb{R^3}
$ with the parametrization $g(s, t) = (t, t^2
, st)$
where $g : [0, 1] × [0, 10] → mathbb{R^3}
$
. Explain why the area of $S$ is equal
to $int_C xdσ$
, where $C$ is the curve in $mathbb{R^2}$
parameterized by $h(t) = (t, t^2
)$,
$h : [0, 10] → mathbb{R^2}$
and Find the area of $S$.
i didn't understand the question at all how can i explain that . Area $S$ =
$int_C x,dsigma$ .
i know that the surface area is given by :
$ int f(x(t),y(t)|r'(t)| { dt}$
but the curve siting in the $[xy]$ plane is $h(t)$ so my guess (might be wrong) that $|r'(t)|$ = $sqrt{4t^2 + 1}$ and $f(x(t),y(t)) = st = sx$ .
integration multivariable-calculus curvature line-integrals
Let $S$ be a surface in $mathbb{R^3}
$ with the parametrization $g(s, t) = (t, t^2
, st)$
where $g : [0, 1] × [0, 10] → mathbb{R^3}
$
. Explain why the area of $S$ is equal
to $int_C xdσ$
, where $C$ is the curve in $mathbb{R^2}$
parameterized by $h(t) = (t, t^2
)$,
$h : [0, 10] → mathbb{R^2}$
and Find the area of $S$.
i didn't understand the question at all how can i explain that . Area $S$ =
$int_C x,dsigma$ .
i know that the surface area is given by :
$ int f(x(t),y(t)|r'(t)| { dt}$
but the curve siting in the $[xy]$ plane is $h(t)$ so my guess (might be wrong) that $|r'(t)|$ = $sqrt{4t^2 + 1}$ and $f(x(t),y(t)) = st = sx$ .
integration multivariable-calculus curvature line-integrals
integration multivariable-calculus curvature line-integrals
edited Dec 29 '18 at 12:25
mechanodroid
27k62446
27k62446
asked Dec 29 '18 at 10:56
Mather Mather
1777
1777
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2 Answers
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The question is only valid for this particular case, not in general.
Let me introduce a notation $mathbf{g}(s,t)$ to denote the vector pointing from origin $(0,0,0)$ to the point $(t,t^2,st)$. Hence, $mathbf{g}(s,t)=t,mathbf{i}+t^2,mathbf{j}+st,mathbf{k}$. The surface area is (refer any book on Advanced Engineering Mathematics)
$$A=int_0^{10}int_0^1 leftlVert frac{partialmathbf{g}}{partial s}timesfrac{partialmathbf{g}}{partial t} rightrVert,text{d}s,text{d}t = int_0^{10}int_0^1 sqrt{4t^4+t^2},text{d}s,text{d}t=int_0^{10}tsqrt{4t^2+1},text{d}t.$$
Incidentally, in this case,
$$int_C x,text{d}sigma=int_0^{10}tsqrt{4t^2+1},text{d}t,$$
since $C$ is parametrised by $(t,t^2)$ and, as you already pointed out, the infinitesimal arc length is $text{d}sigma=sqrt{4t^2+1},text{d}t$.
add a comment |
Notice that your surface $S$ is the area between the curves $tmapsto (t,t^2,0)$ and $t mapsto (t,t^2,t)$.
Informally, if you consider the curve $C$ given by $tmapsto (t,t^2)$ as the $x$-axis, you are calculating the area between the $x$-axis and the curve $y = x$.
Hence $$text{Area}(S) = int_{C} x,dsigma$$
add a comment |
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2 Answers
2
active
oldest
votes
2 Answers
2
active
oldest
votes
active
oldest
votes
active
oldest
votes
The question is only valid for this particular case, not in general.
Let me introduce a notation $mathbf{g}(s,t)$ to denote the vector pointing from origin $(0,0,0)$ to the point $(t,t^2,st)$. Hence, $mathbf{g}(s,t)=t,mathbf{i}+t^2,mathbf{j}+st,mathbf{k}$. The surface area is (refer any book on Advanced Engineering Mathematics)
$$A=int_0^{10}int_0^1 leftlVert frac{partialmathbf{g}}{partial s}timesfrac{partialmathbf{g}}{partial t} rightrVert,text{d}s,text{d}t = int_0^{10}int_0^1 sqrt{4t^4+t^2},text{d}s,text{d}t=int_0^{10}tsqrt{4t^2+1},text{d}t.$$
Incidentally, in this case,
$$int_C x,text{d}sigma=int_0^{10}tsqrt{4t^2+1},text{d}t,$$
since $C$ is parametrised by $(t,t^2)$ and, as you already pointed out, the infinitesimal arc length is $text{d}sigma=sqrt{4t^2+1},text{d}t$.
add a comment |
The question is only valid for this particular case, not in general.
Let me introduce a notation $mathbf{g}(s,t)$ to denote the vector pointing from origin $(0,0,0)$ to the point $(t,t^2,st)$. Hence, $mathbf{g}(s,t)=t,mathbf{i}+t^2,mathbf{j}+st,mathbf{k}$. The surface area is (refer any book on Advanced Engineering Mathematics)
$$A=int_0^{10}int_0^1 leftlVert frac{partialmathbf{g}}{partial s}timesfrac{partialmathbf{g}}{partial t} rightrVert,text{d}s,text{d}t = int_0^{10}int_0^1 sqrt{4t^4+t^2},text{d}s,text{d}t=int_0^{10}tsqrt{4t^2+1},text{d}t.$$
Incidentally, in this case,
$$int_C x,text{d}sigma=int_0^{10}tsqrt{4t^2+1},text{d}t,$$
since $C$ is parametrised by $(t,t^2)$ and, as you already pointed out, the infinitesimal arc length is $text{d}sigma=sqrt{4t^2+1},text{d}t$.
add a comment |
The question is only valid for this particular case, not in general.
Let me introduce a notation $mathbf{g}(s,t)$ to denote the vector pointing from origin $(0,0,0)$ to the point $(t,t^2,st)$. Hence, $mathbf{g}(s,t)=t,mathbf{i}+t^2,mathbf{j}+st,mathbf{k}$. The surface area is (refer any book on Advanced Engineering Mathematics)
$$A=int_0^{10}int_0^1 leftlVert frac{partialmathbf{g}}{partial s}timesfrac{partialmathbf{g}}{partial t} rightrVert,text{d}s,text{d}t = int_0^{10}int_0^1 sqrt{4t^4+t^2},text{d}s,text{d}t=int_0^{10}tsqrt{4t^2+1},text{d}t.$$
Incidentally, in this case,
$$int_C x,text{d}sigma=int_0^{10}tsqrt{4t^2+1},text{d}t,$$
since $C$ is parametrised by $(t,t^2)$ and, as you already pointed out, the infinitesimal arc length is $text{d}sigma=sqrt{4t^2+1},text{d}t$.
The question is only valid for this particular case, not in general.
Let me introduce a notation $mathbf{g}(s,t)$ to denote the vector pointing from origin $(0,0,0)$ to the point $(t,t^2,st)$. Hence, $mathbf{g}(s,t)=t,mathbf{i}+t^2,mathbf{j}+st,mathbf{k}$. The surface area is (refer any book on Advanced Engineering Mathematics)
$$A=int_0^{10}int_0^1 leftlVert frac{partialmathbf{g}}{partial s}timesfrac{partialmathbf{g}}{partial t} rightrVert,text{d}s,text{d}t = int_0^{10}int_0^1 sqrt{4t^4+t^2},text{d}s,text{d}t=int_0^{10}tsqrt{4t^2+1},text{d}t.$$
Incidentally, in this case,
$$int_C x,text{d}sigma=int_0^{10}tsqrt{4t^2+1},text{d}t,$$
since $C$ is parametrised by $(t,t^2)$ and, as you already pointed out, the infinitesimal arc length is $text{d}sigma=sqrt{4t^2+1},text{d}t$.
edited Dec 29 '18 at 12:24
answered Dec 29 '18 at 12:17
ZxcvasdfZxcvasdf
384
384
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Notice that your surface $S$ is the area between the curves $tmapsto (t,t^2,0)$ and $t mapsto (t,t^2,t)$.
Informally, if you consider the curve $C$ given by $tmapsto (t,t^2)$ as the $x$-axis, you are calculating the area between the $x$-axis and the curve $y = x$.
Hence $$text{Area}(S) = int_{C} x,dsigma$$
add a comment |
Notice that your surface $S$ is the area between the curves $tmapsto (t,t^2,0)$ and $t mapsto (t,t^2,t)$.
Informally, if you consider the curve $C$ given by $tmapsto (t,t^2)$ as the $x$-axis, you are calculating the area between the $x$-axis and the curve $y = x$.
Hence $$text{Area}(S) = int_{C} x,dsigma$$
add a comment |
Notice that your surface $S$ is the area between the curves $tmapsto (t,t^2,0)$ and $t mapsto (t,t^2,t)$.
Informally, if you consider the curve $C$ given by $tmapsto (t,t^2)$ as the $x$-axis, you are calculating the area between the $x$-axis and the curve $y = x$.
Hence $$text{Area}(S) = int_{C} x,dsigma$$
Notice that your surface $S$ is the area between the curves $tmapsto (t,t^2,0)$ and $t mapsto (t,t^2,t)$.
Informally, if you consider the curve $C$ given by $tmapsto (t,t^2)$ as the $x$-axis, you are calculating the area between the $x$-axis and the curve $y = x$.
Hence $$text{Area}(S) = int_{C} x,dsigma$$
answered Dec 29 '18 at 12:23
mechanodroidmechanodroid
27k62446
27k62446
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