Application of Perturbation Theory in Classical Mechanics - Shashidhar Guttula
Outline Classical Mechanics Perturbation Theory Applications of the theory Simulation of Mechanical systems Conclusions References
Classical Mechanics Minimum Principles Central Force Theorem Rigid Body Motion Oscillations Theory of Relativity Chaos
Perturbation Theory Mathematical Method used to find an approximate solution to a problem which cannot be solved exactly An expression for the desired solution in terms of a *power series
Method of Perturbation theory Technique for obtaining approx solution based on smallness of perturbation Hamiltonian and on the assumed smallness of the changes in the solutions If the change in the Hamiltonian is small, the overall effect of the perturbation on the motion can be large Perturbation solution should be carefully analyzed so it is physically correct
Classical Perturbation theory Time Dependent Perturbation theory Time Independent Perturbation theory Classical Perturbation Theory is more complicated than Quantum Perturbation theory Many similarities between classical perturbation theory and quantum perturbation theory
Solve :Perturbation theory problems A regular perturbation is an equation of the form : D (x; φ)=0 Write the solution as a power series : xsol=x0+x1+x2+x3+….. Insert the power series into the equation and rearrange to a new power series in D(xsol;”)=D(x0+x1+x2+x3+…..); =P0(x0;0)+P1(x0;x1)+P2(x0;x1;x2)+…. Set each coefficient in the power series equal to zero and solve the resulting systems P0(x0;0)=D(x0;0)=0 P1(x0;x1)=0 P2(x0;x1;x2)=0
Idea applies in many contexts To Obtain Approximate solutions to algebraic and transcendental equations Approximate expressions to definite integrals Ordinary and partial differential equations
Perturbation Theory Vs Numerical Techniques Produce analytical approximations that reveal the essential dependence of the exact solution on the parameters in a more satisfactory way Problems which cannot be easily solved numerically may yield to perturbation method Perturbation analysis is often Complementary to Numerical methods
Applications in Classical Mechanics Projectile Motion Damped Harmonic Oscillator Three Body Problem Spring-mass system
Projectile Motion In 2-D,without air resistance parameters Initial velocity:V0 ; Angle of elevation :θ Add the effect of air resistance to the motion of the projectile Equations of motion change The range under this assumption decreases. *Force caused by air resistance is directly proportional to the projectile velocity
Force Drag k << g/V Effect of air resistance : projectile motion
Range Vs Retarding Force Constant ‘k’ from P.T
Damped Harmonic Oscillator Taking Putting
Harmonic Oscillator (contd.) First Order Term Second Order Term General Solution through perturbation Exact Solution
Three Body Problem The varying perturbation of the Sun’s gravity on the Earth-Moon orbit as Earth revolves around the Sun Secular Perturbation theory Long-period oscillations in planetary orbits It has the potential to explain many of the orbital properties of these systems Application for planetary systems with three or four planets It determines orbital spacing, eccentricities and inclinations in planetary systems
Spring-mass system with no damping
Input :Impulse Signal
Displacement Vs Time
Spring-mass system with damping factor
Input Impulse Signal
Displacement Vs Time
Conclusions Use of Perturbation theory in mechanical systems Math involved in it is complicated Theory which is vast has its application Quantum Mechanics High Energy Particle Physics Semiconductor Physics Its like an art must be learned by doing
References Classical Dynamics of particles and systems ,Marion &Thornton 4th Edition Classical Mechanics, Goldstein, Poole & Safko, Third Edition A First look at Perturbation theory ,James G.Simmonds & James E.Mann,Jr Perturbation theory in Classical Mechanics, F M Fernandez,Eur.J.Phys.18 (1997) Introduction to Perturbation Techniques ,Nayfeh. A.H