Obtain first two terms in the asymptotic approximation $epsilon x^3+x^2+2x-3=0$
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Consider the singularly perturbed cubic equation
$$epsilon x^3+x^2+2x-3=0$$
where $epsilon >0$ is a small parameter. This equation has two regularly perturbed roots and one singularly perturbed root.
i. Obtain the first two terms in the asymptotic approximation of the regularly perturbed roots as $epsilon to 0$
ii. Use the substitution $x(epsilon) = frac{z(epsilon)}{epsilon}$ to obtain the first two terms of an asymptotic approximation of the singularyl perturbed solution of this equation as $epsilon to 0$
My solutions:
i. Look for the solution of the form
$$x(epsilon) = x_0 + epsilon x_1 + epsilon^2 x_2 +...$$
formally sub into equation
$$epsilon(x_0 + epsilon x_1 + epsilon^2 x_2 +...)^3 + (x_0 + epsilon x_1 + epsilon^2 x_2 +...)^2 + 2(x_0 + epsilon x_1 + epsilon^2 x_2 +...) - 3 = 0$$
then we have
$$epsilon(x^3_0+epsilon(3x^2_0x_1) + epsilon^2(3x_0x_1^2+3x_0^2x_2)+...)+(x^2_0+epsilon(2x_0x_1)+epsilon^2(x_1^2+2x_0x_2)+...)+2(x_0+epsilon x_1+epsilon^2x_2+...)-3=0$$
comparing coefficients of powers of $epsilon$
$O(epsilon^0) = x^2_0+2x_0-3=0$
$ implies x_0=3,1$
$O(epsilon^1) = x_0+3x^2_0x_1+2x_0x_1+2x_1=0$
$ implies $ if $x_0=3 space$then $x_1=frac{-3}{35}$ and if $x_0=-1$ then $x_1 = frac{1}{3}$
That is my current answer for i.
I have begun to answer part ii using the change of variable given, however im not sure if I am along the right lines by answering it in the same manner as part i. TIA
asymptotics perturbation-theory
$endgroup$
add a comment |
$begingroup$
Consider the singularly perturbed cubic equation
$$epsilon x^3+x^2+2x-3=0$$
where $epsilon >0$ is a small parameter. This equation has two regularly perturbed roots and one singularly perturbed root.
i. Obtain the first two terms in the asymptotic approximation of the regularly perturbed roots as $epsilon to 0$
ii. Use the substitution $x(epsilon) = frac{z(epsilon)}{epsilon}$ to obtain the first two terms of an asymptotic approximation of the singularyl perturbed solution of this equation as $epsilon to 0$
My solutions:
i. Look for the solution of the form
$$x(epsilon) = x_0 + epsilon x_1 + epsilon^2 x_2 +...$$
formally sub into equation
$$epsilon(x_0 + epsilon x_1 + epsilon^2 x_2 +...)^3 + (x_0 + epsilon x_1 + epsilon^2 x_2 +...)^2 + 2(x_0 + epsilon x_1 + epsilon^2 x_2 +...) - 3 = 0$$
then we have
$$epsilon(x^3_0+epsilon(3x^2_0x_1) + epsilon^2(3x_0x_1^2+3x_0^2x_2)+...)+(x^2_0+epsilon(2x_0x_1)+epsilon^2(x_1^2+2x_0x_2)+...)+2(x_0+epsilon x_1+epsilon^2x_2+...)-3=0$$
comparing coefficients of powers of $epsilon$
$O(epsilon^0) = x^2_0+2x_0-3=0$
$ implies x_0=3,1$
$O(epsilon^1) = x_0+3x^2_0x_1+2x_0x_1+2x_1=0$
$ implies $ if $x_0=3 space$then $x_1=frac{-3}{35}$ and if $x_0=-1$ then $x_1 = frac{1}{3}$
That is my current answer for i.
I have begun to answer part ii using the change of variable given, however im not sure if I am along the right lines by answering it in the same manner as part i. TIA
asymptotics perturbation-theory
$endgroup$
$begingroup$
Your $O(epsilon)$ equation is incorrect, you need the $O(1)$ terms of $x^3$, which is just $x_0^3$, and the $O(epsilon)$ terms from $x^2$ and $x$, so you should have $x_0^3+2x_0x_1+2x_1=0$. After you substitute for $z$ in ii., the process is the same as in i.
$endgroup$
– David
Dec 13 '18 at 19:10
add a comment |
$begingroup$
Consider the singularly perturbed cubic equation
$$epsilon x^3+x^2+2x-3=0$$
where $epsilon >0$ is a small parameter. This equation has two regularly perturbed roots and one singularly perturbed root.
i. Obtain the first two terms in the asymptotic approximation of the regularly perturbed roots as $epsilon to 0$
ii. Use the substitution $x(epsilon) = frac{z(epsilon)}{epsilon}$ to obtain the first two terms of an asymptotic approximation of the singularyl perturbed solution of this equation as $epsilon to 0$
My solutions:
i. Look for the solution of the form
$$x(epsilon) = x_0 + epsilon x_1 + epsilon^2 x_2 +...$$
formally sub into equation
$$epsilon(x_0 + epsilon x_1 + epsilon^2 x_2 +...)^3 + (x_0 + epsilon x_1 + epsilon^2 x_2 +...)^2 + 2(x_0 + epsilon x_1 + epsilon^2 x_2 +...) - 3 = 0$$
then we have
$$epsilon(x^3_0+epsilon(3x^2_0x_1) + epsilon^2(3x_0x_1^2+3x_0^2x_2)+...)+(x^2_0+epsilon(2x_0x_1)+epsilon^2(x_1^2+2x_0x_2)+...)+2(x_0+epsilon x_1+epsilon^2x_2+...)-3=0$$
comparing coefficients of powers of $epsilon$
$O(epsilon^0) = x^2_0+2x_0-3=0$
$ implies x_0=3,1$
$O(epsilon^1) = x_0+3x^2_0x_1+2x_0x_1+2x_1=0$
$ implies $ if $x_0=3 space$then $x_1=frac{-3}{35}$ and if $x_0=-1$ then $x_1 = frac{1}{3}$
That is my current answer for i.
I have begun to answer part ii using the change of variable given, however im not sure if I am along the right lines by answering it in the same manner as part i. TIA
asymptotics perturbation-theory
$endgroup$
Consider the singularly perturbed cubic equation
$$epsilon x^3+x^2+2x-3=0$$
where $epsilon >0$ is a small parameter. This equation has two regularly perturbed roots and one singularly perturbed root.
i. Obtain the first two terms in the asymptotic approximation of the regularly perturbed roots as $epsilon to 0$
ii. Use the substitution $x(epsilon) = frac{z(epsilon)}{epsilon}$ to obtain the first two terms of an asymptotic approximation of the singularyl perturbed solution of this equation as $epsilon to 0$
My solutions:
i. Look for the solution of the form
$$x(epsilon) = x_0 + epsilon x_1 + epsilon^2 x_2 +...$$
formally sub into equation
$$epsilon(x_0 + epsilon x_1 + epsilon^2 x_2 +...)^3 + (x_0 + epsilon x_1 + epsilon^2 x_2 +...)^2 + 2(x_0 + epsilon x_1 + epsilon^2 x_2 +...) - 3 = 0$$
then we have
$$epsilon(x^3_0+epsilon(3x^2_0x_1) + epsilon^2(3x_0x_1^2+3x_0^2x_2)+...)+(x^2_0+epsilon(2x_0x_1)+epsilon^2(x_1^2+2x_0x_2)+...)+2(x_0+epsilon x_1+epsilon^2x_2+...)-3=0$$
comparing coefficients of powers of $epsilon$
$O(epsilon^0) = x^2_0+2x_0-3=0$
$ implies x_0=3,1$
$O(epsilon^1) = x_0+3x^2_0x_1+2x_0x_1+2x_1=0$
$ implies $ if $x_0=3 space$then $x_1=frac{-3}{35}$ and if $x_0=-1$ then $x_1 = frac{1}{3}$
That is my current answer for i.
I have begun to answer part ii using the change of variable given, however im not sure if I am along the right lines by answering it in the same manner as part i. TIA
asymptotics perturbation-theory
asymptotics perturbation-theory
asked Dec 13 '18 at 12:32
Ben JonesBen Jones
19111
19111
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Your $O(epsilon)$ equation is incorrect, you need the $O(1)$ terms of $x^3$, which is just $x_0^3$, and the $O(epsilon)$ terms from $x^2$ and $x$, so you should have $x_0^3+2x_0x_1+2x_1=0$. After you substitute for $z$ in ii., the process is the same as in i.
$endgroup$
– David
Dec 13 '18 at 19:10
add a comment |
$begingroup$
Your $O(epsilon)$ equation is incorrect, you need the $O(1)$ terms of $x^3$, which is just $x_0^3$, and the $O(epsilon)$ terms from $x^2$ and $x$, so you should have $x_0^3+2x_0x_1+2x_1=0$. After you substitute for $z$ in ii., the process is the same as in i.
$endgroup$
– David
Dec 13 '18 at 19:10
$begingroup$
Your $O(epsilon)$ equation is incorrect, you need the $O(1)$ terms of $x^3$, which is just $x_0^3$, and the $O(epsilon)$ terms from $x^2$ and $x$, so you should have $x_0^3+2x_0x_1+2x_1=0$. After you substitute for $z$ in ii., the process is the same as in i.
$endgroup$
– David
Dec 13 '18 at 19:10
$begingroup$
Your $O(epsilon)$ equation is incorrect, you need the $O(1)$ terms of $x^3$, which is just $x_0^3$, and the $O(epsilon)$ terms from $x^2$ and $x$, so you should have $x_0^3+2x_0x_1+2x_1=0$. After you substitute for $z$ in ii., the process is the same as in i.
$endgroup$
– David
Dec 13 '18 at 19:10
add a comment |
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$begingroup$
Your $O(epsilon)$ equation is incorrect, you need the $O(1)$ terms of $x^3$, which is just $x_0^3$, and the $O(epsilon)$ terms from $x^2$ and $x$, so you should have $x_0^3+2x_0x_1+2x_1=0$. After you substitute for $z$ in ii., the process is the same as in i.
$endgroup$
– David
Dec 13 '18 at 19:10