QUESTION IMAGE
Question
use the phase-plane method to show that the solution to the nonlinear second-order differential equation \\(x + 6x - x^2 = 0\\) that satisfies \\(x(0) = 1\\) and \\(x(0) = 0\\) is periodic.
let \\(\frac{dx}{dt} = y\\). then the differential equation \\(\frac{dy}{dx} =\\) can be solved by separating variables. it follows that the general solution is , and since \\(\mathbf{x}(0) = (x(0), x(0)) = (1, 0)\\) then the particular solution is . but for each \\(x\\) such that \\(4 - 2\sqrt{6} < x < 1\\), the particular solution has corresponding value(s) of \\(y\\). therefore \\(\mathbf{x}(t)\\) is a periodic solution.
<pre_analysis>
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"concepts_used": [
"Phase Portrait Analysis",
"Nonlinear Systems of ODEs"
],
"new_concepts": [
"Phase-Plane Method",
"Periodic Solutions of ODEs"
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"current_concepts": [
"Phase Portrait Analysis",
"Nonlinear Systems of ODEs",
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</pre_analysis>
<reasoning>
Convert to a first-order system
Using the Nonlinear Systems of ODEs knowledge point
\[
\]
Formulate the phase-plane equation
Using the Phase Portrait Analysis knowledge point
\[
\frac{dy}{dx} = \frac{dy/dt}{dx/dt} = \frac{x^2 - 6x}{y}
\]
Solve by separation of variables
Using the Phase Portrait Analysis knowledge point
\[
\]
Apply the initial conditions
Using the Phase Portrait Analysis knowledge point
\[
\]
Analyze the periodic behavior
Using the Phase Portrait Analysis knowledge point
\[
\]
For each \(x\) in the interval \(4 - 2\sqrt{6} < x < 1\), the term inside the square root is strictly positive, yielding two real, symmetric values of \(y\).
</reasoning>
<answer>
Use the phase-plane method to show that the solution to the nonlinear second-order differential equation \(x'' + 6x - x^2 = 0\) that satisfies \(x(0) = 1\) and \(x'(0) = 0\) is periodic.
Let \(\frac{dx}{dt} = y\). Then the differential equation \(\frac{dy}{dx} =\) <blank>\(\frac{x^2-6x}{y}\)</blank> can be solved by separating variables. It follows that the general solution is <blank>\(y^2 - \frac{2}{3}x^3 + 6x^2 = C\)</blank>, and since \(\mathbf{X}(0) = (x(0), x'(0)) = (1, 0)\) then the particular solution is <blank>\(y^2 - \frac{2}{3}x^3 + 6x^2 = \frac{16}{3}\)</blank>. But for each \(x\) such that \(4 - 2\sqrt{6} < x < 1\), the particular solution has <blank>two real</blank> corresponding value(s) of \(y\). Therefore \(\mathbf{X}(t)\) is a periodic solution.
</answer>
<post_analysis>
{
"subject": "Mathematics",
"question_type": "Fill-in-the-blank",
"knowledge_point": [
"Mathematics",
"Calculus",
"Nonlinear Systems of ODEs"
]
}
</post_analysis>
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<pre_analysis>
{
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"question_count": 1,
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"step_cot",
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"concepts_used": [
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}
</pre_analysis>
<reasoning>
Convert to a first-order system
Using the Nonlinear Systems of ODEs knowledge point
\[
\]
Formulate the phase-plane equation
Using the Phase Portrait Analysis knowledge point
\[
\frac{dy}{dx} = \frac{dy/dt}{dx/dt} = \frac{x^2 - 6x}{y}
\]
Solve by separation of variables
Using the Phase Portrait Analysis knowledge point
\[
\]
Apply the initial conditions
Using the Phase Portrait Analysis knowledge point
\[
\]
Analyze the periodic behavior
Using the Phase Portrait Analysis knowledge point
\[
\]
For each \(x\) in the interval \(4 - 2\sqrt{6} < x < 1\), the term inside the square root is strictly positive, yielding two real, symmetric values of \(y\).
</reasoning>
<answer>
Use the phase-plane method to show that the solution to the nonlinear second-order differential equation \(x'' + 6x - x^2 = 0\) that satisfies \(x(0) = 1\) and \(x'(0) = 0\) is periodic.
Let \(\frac{dx}{dt} = y\). Then the differential equation \(\frac{dy}{dx} =\) <blank>\(\frac{x^2-6x}{y}\)</blank> can be solved by separating variables. It follows that the general solution is <blank>\(y^2 - \frac{2}{3}x^3 + 6x^2 = C\)</blank>, and since \(\mathbf{X}(0) = (x(0), x'(0)) = (1, 0)\) then the particular solution is <blank>\(y^2 - \frac{2}{3}x^3 + 6x^2 = \frac{16}{3}\)</blank>. But for each \(x\) such that \(4 - 2\sqrt{6} < x < 1\), the particular solution has <blank>two real</blank> corresponding value(s) of \(y\). Therefore \(\mathbf{X}(t)\) is a periodic solution.
</answer>
<post_analysis>
{
"subject": "Mathematics",
"question_type": "Fill-in-the-blank",
"knowledge_point": [
"Mathematics",
"Calculus",
"Nonlinear Systems of ODEs"
]
}
</post_analysis>