Introduction to Mechanical Vibrations. Ronald J. Anderson. Читать онлайн. Newlib. NEWLIB.NET

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Автор:	Ronald J. Anderson
Издательство:	John Wiley & Sons Limited
Серия:
Жанр произведения:	Физика
Год издания:	0
isbn:	9781119053644

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Geometric Nonlinearities

Both the simple pendulum with the EOM (Equation of Motion)

(1.49) equation

and the bead on a rotating wire with the EOM

(1.50) equation

have geometric nonlinearities arising from the sine and cosine terms. They will both be addressed in the following, starting with the simple pendulum.

1.3.1.1 Linear EOM for a Simple Pendulum

The nonlinear differential equation of motion for the pendulum (Equation 1.44) is valid for any range of motion. The difficulty is that we can't solve nonlinear differential equations without resorting to numerical methods. We get around this problem by linearizing the differential equation because we have had courses on how to solve linear differential equations.

To do this, we consider small motions near the stable equilibrium state. Let images in Equation 1.44 be replaced by images where images is a very small angle and images is the equilibrium value of images . That is,

and, differentiating with the knowledge that images is constant, we find

and then

Substituting into Equation 1.44 yields

(1.51) equation

We can use the trigonometric identity for the sine of the sum of two angles⁷ to write

(1.52) equation

We now consider rewriting Equation 1.52 under the condition where images is a very small angle. The small angle conditions on the sine and cosine are derived from their Maclaurin's Series expansions. The expansions are

and

If images is very small, then higher powers of images are much smaller and are negligible⁸ in the series. We therefore approximate the sine and cosine with

and

Equation 1.52 can then be written as

(1.53) equation

and the equation of motion (Equation 1.51) becomes

(1.54) equation

Note the constant term images that appears in Equation 1.54. This is the term that was set to zero to determine the equilibrium state (see Equation 1.45) and it is still equal to zero so it can be removed. The equilibrium condition is always a set of constant terms that must be zero for the system not to move and that set of constant terms always reappears in the linearized equation of motion. After removing the equilibrium condition, the linearized equation of motion for the pendulum becomes

(1.55) equation

This equation is valid for motion about either of the two equilibrium states we found (i.e. images with images and images with images ). We write

(1.56) equation

and

(1.57) equation

Equation 1.56 will yield oscillating solutions (i.e. vibrations – more to come later) and Equation 1.57 will yield growing exponential solutions, showing that the system really doesn't want to stay in the unstable upright position.

1.3.1.2 Linear EOM for the Bead on the Wire

The EOM for the bead on the rotating wire is

(1.58) equation

As we did for the simple pendulum, we let Скачать книгу