Multiple-prism dispersion theory

From formulasearchengine
Revision as of 20:39, 25 January 2014 by en>Corrigendas (added ref)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

In a real spring–mass system, the spring has a non-negligible mass m. Since not all of the spring's length moves at the same velocity u as the suspended mass M, its kinetic energy is not equal to mu2/2. As such, m cannot be simply added to M in order to determine the frequency of oscillation, and the effective mass of the spring is defined as the mass that needs to be added to M in order to correctly predict the behavior of the system.

Ideal uniform spring

vertical spring-mass system

The effective mass of the spring in a spring-mass system when using an ideal spring of uniform linear density is 1/3 of the mass of the spring and is independent of the direction of the spring-mass system (i.e., horizontal, vertical, and oblique systems all have the same effective mass). This is because external acceleration does not affect the period of motion around the equilibrium point.

We can find the effective mass of the spring by finding its kinetic energy. This requires adding all the length elements' kinetic energy, and requires the following integral:

Keff=m12u2dm

Since the spring is uniform, dm=(dyL)m, where L is the length of the spring. Hence,

Keff=0L12u2(dyL)m
=12mL0Lu2dy

The velocity of each mass element of the spring is directly proportional to its length, i.e. u=vyL, from which it follows:

Keff=12mL0L(vyL)2dy
=12mL3v20Ly2dy
=12mL3v2[y33]0L
=12m3v2

Comparing to the expected original kinetic energy formula 12mv2, we can conclude that effective mass of spring in this case is m/3. Using this result, we can write down the equation of motion of the spring by writing the Lagrangian in terms of the displacement x from the spring's unstretched position (ignoring constant potential terms and taking the upwards direction as positive):

L=TV
=12m3x˙2+12Mv212kx2mgx2Mgx

Note that g here is the acceleration of gravity along the spring. Using the Euler-Lagrange equation, we arrive at the equation of motion:

(m3+M)x¨=kxmg2Mg

We can find the equilibrium point xeq by letting the acceleration be zero:

xeq=1k(mg2+Mg)

Defining x¯=xxeq, the equation of motion becomes:

(m3+M)x¯¨=kx¯

This is the equation for a simple harmonic oscillator with period:

τ=2π(M+m/3k)1/2

So we can see that the effective mass of the spring added to the mass of the load gives us the "effective total mass" of the system that must be used in the standard formula 2π(mk)1/2 in order to determine the period of oscillation.

General case

As seen above, the effective mass of a spring does not depend upon "external" factors such as the acceleration of gravity along it. In fact, for a non-uniform spring, the effective mass solely depends on its linear density ρ(x) along its length:

meff=m12u2dm
=0L12u2ρ(x)dx
=0L12(vxL)2ρ(x)dx
=12[0Lx2L2ρ(x)dx]v2

So the effective mass of a spring is:

meff=0Lx2L2ρ(x)dx

This result also shows that meffm, with meff=m occurring in the case of an unphysical spring whose mass is located purely at the end farthest from the support.

Real spring

The above calculations assume that the stiffness coefficient of the spring does not depend on its length. However, this is not the case for real springs. For small values of M/m, the displacement is not so large as to cause elastic deformation. Jun-ichi Ueda and Yoshiro Sadamoto have foundPotter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park. that as M/m increases beyond 7, the effective mass of a spring in a vertical spring-mass system becomes smaller than Rayleigh's value m/3 and eventually reaches negative values. This unexpected behavior of the effective mass can be explained in terms of the elastic after-effect (which is the spring's not returning to its original length after the load is removed).

See also

External links