4.6.24 · D4 · HinglishOrdinary Differential Equations

ExercisesLinearization of nonlinear systems

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4.6.24 · D4 · Maths › Ordinary Differential Equations › Nonlinear systems ka Linearization

Ye recurring tools tumhare paas ready hone chahiye:

  • Jacobian — partial slopes ki matrix (parent note mein Taylor Series expansion se bani).
  • Trace aur determinant , equilibrium par evaluate kiya hua.
  • Eigenvalue formula .
Figure — Linearization of nonlinear systems

Upar wali picture tumhara map hai: neeche ke har problem mein is plane par ek point aata hai.


Level 1 — Recognition

L1.1

Inn mein se kaun sa point ka equilibrium hai? Candidates: , , .

Recall Solution

Ek equilibrium ke liye dono aur chahiye.

  • : ✔, ✔. Equilibrium.
  • : ✔ lekin ✘.
  • : ✔, ✔. Equilibrium.

Answer: aur .

L1.2

ka general Jacobian likho.

Recall Solution

. . Dhyaan do ki abhi bhi andar hai — yeh abhi linear system nahi hai; isse kisi point par evaluate karna zaroori hai.


Level 2 — Application

L2.1

Classify karo linear system ke equilibrium ko (already evaluated).

Recall Solution

Triangular matrix → eigenvalues diagonal par hote hain: . Dono real, dono negative → stable node. Shortcut se check karo: , , → real same-sign, ⇒ stable node. ✔

L2.2

ke liye, par equilibrium ko classify karo.

Recall Solution

mein substitute karo: , . . Complex with unstable spiral.

L2.3

Same system, ko classify karo.

Recall Solution

substitute karo: , . → real opposite-sign eigenvalues → saddle (unstable). Explicitly . ✔


Level 3 — Analysis

L3.1

ke saare equilibria find aur classify karo.

Recall Solution

Equilibria: aur . Points: . Jacobian: ; .

  • : , center (inconclusive).
  • : , , saddle. (.)
  • : same (kyunki ), same result → saddle.

L3.2

Ek biological model (ek Lotka-Volterra Predator Prey jaisa): , . Interior equilibrium (dono positive) find karo aur classify karo.

Recall Solution

Interior: (nonzero) cancel karo: aur . Subtract karo: . Phir . Point . Jacobian. . . par: , , , . saddle (unstable). Explicitly , yaani : opposite signs. ✔


Level 4 — Synthesis

L4.1

Parameter sweep. (ek damped oscillator) ke liye, origin ko classify karo jab saare real values par vary karta hai. Boundary cases bhi include karo.

Recall Solution

, , hamesha. Discriminant .

range eigenvalues type
real, dono () stable node
repeated stable (degenerate) node
complex, stable spiral
center (inconclusive)
complex, unstable spiral
repeated unstable node
real, dono unstable node

Physical reading: damping hai. Positive damping () energy drain karta hai → stable; undamped center hai; negative damping energy pump karta hai → unstable. Stability exactly par flip hoti hai jahan eigenvalues imaginary axis cross karte hain. Map figure par crossing dekho.

Figure — Linearization of nonlinear systems

L4.2

Ek system design karo. Aise explicit (polynomial) construct karo jiska par equilibrium ho jo stable spiral ho. Verify karo.

Recall Solution

Strategy: shifted coordinate use karke equilibrium par rakho, aur aisa Jacobian choose karo jisme ho. Target lo : , , → stable spiral. ✔ Shifted coordinates mein exactly is Jacobian wala linear-in-shift field: Equilibrium check: par dono bracket terms zero ho jaate hain → ✔. Iska Jacobian upar wali constant matrix hai (partials: ). Eigenvalues → decaying oscillation. Stable spiral at .


Level 5 — Mastery

L5.1

Full portrait. Damping wale pendulum ke liye ( small), jise likha gaya hai, aur classify karo, aur explain karo ki damping parent note ke undamped answer ko kaise badalta hai.

Recall Solution

.

  • Bottom : , . , , disc small ke liye → complex, stable spiral. Damping undamped center ko genuine sink mein badal deta hai — ab Hartman–Grobman apply hota hai kyunki .
  • Top : , . , saddle (unstable), damping se unchanged (abhi bhi ). : ek positive, ek negative. ✔

Moral: damping () bottom par marginal center tod deta hai aur use decisively stable banata hai, lekin intrinsically unstable upright saddle ko nahi bacha sakta.

L5.2

Non-hyperbolic showdown. ke liye, dikhao ki origin non-hyperbolic hai, phir ek Lyapunov function use karke uski true stability argue karo.

Recall Solution

Linearize. ; . par: , eigenvalues . Ek zero eigenvalue → non-hyperbolic → -direction mein linearization inconclusive. Lyapunov. Try karo , sirf origin par. aur sirf origin par. Kyunki aur origin ke bahar, origin asymptotically stable hai — bhale hi linearization nahi bata sakti thi. Nonlinear term karta hai, bas slowly.

L5.3

Bifurcation reasoning. mein, find karo ki ke se guzarne par equilibria ki sankhya aur stability kaise badlti hai.

Recall Solution

Equilibria: aur .

  • : koi real nahi → koi equilibria nahi.
  • : single point ; , non-hyperbolic (pair ka janam).
  • : do points .
    • par: , eigenvalues dono stable node.
    • par: , eigenvalues opposite signs → saddle.

Yeh ek saddle–node bifurcation hai: jab cross karta hai, ek stable node aur ek saddle kuch se milkar appear hote hain. Exact crossing point non-hyperbolic hai — precisely wahan linearization chup ho jaata hai.


Recall Ek-line master summary

Har equilibrium find karo → Jacobian → wahan evaluate karo ya eigenvalues → classify karo — aur agar koi ho, ruko aur Lyapunov dhundo.

Master check
Agar hai toh point hamesha saddle (unstable) hoga chahe kuch bhi ho, kyunki eigenvalues ke opposite signs hote hain.