Study of Spring-Mass Systems

Example 9. Equal Masses, Unequal spring constants. Find the general solution to the system of D. E.'s and plot the solution curves.

[Graphics:Images/SpringMassMod_gr_315.gif]

Solution 9.

[Graphics:../Images/SpringMassMod_gr_317.gif]

Put the D.E.'s in operator form and eliminate y to obtain a fourth order D.E. for x, and find the roots of its characteristic equation.

[Graphics:../Images/SpringMassMod_gr_319.gif]

The roots are pure complex, [Graphics:../Images/SpringMassMod_gr_320.gif] , and the natural frequencies , respectively. The general solution is formed as follows.

[Graphics:../Images/SpringMassMod_gr_323.gif]

Aside. The eigenfrequencies can be obtained by taking the square root of the eigenvalues of the matrix .

It is useful to look at the two natural modes of oscillation of the spring mass system and they exhibit the natural frequencies , respectively.

[Graphics:../Images/SpringMassMod_gr_329.gif]

Plot the functions and . In this mode of oscillation the masses are moving in opposite directions.

[Graphics:../Images/SpringMassMod_gr_333.gif]

[Graphics:../Images/SpringMassMod_gr_334.gif]

Plot the functions and . In this mode of oscillation the masses are moving in the same directions.

[Graphics:../Images/SpringMassMod_gr_338.gif]

[Graphics:../Images/SpringMassMod_gr_339.gif]

Assume that the equilibrium position along the horizontal axis is 2 and 6. The two masses move in the same direction with the frequency ,
as seen in the next graph, where time is along the vertical axis.

[Graphics:../Images/SpringMassMod_gr_342.gif]

[Graphics:../Images/SpringMassMod_gr_343.gif]

Assume that the equilibrium position along the horizontal axis is 2 and 6. The two masses move in opposite directions with the frequency ,
as seen in the next graph, where time is along the vertical axis.

[Graphics:../Images/SpringMassMod_gr_346.gif]

[Graphics:../Images/SpringMassMod_gr_347.gif]