Question 4.2: Find the steady state response of an undamped SDOF system to...

The steady state response of an undamped SDOF subjected to a harmonic
excitation p_{0} sin ϖ t is given as follows:

 x(t)=\frac{p_{0}}{k} \frac{1}{(1-\beta ^{2})} \sin \bar{\omega } t

where β = ϖ/ω = n ϖ_{1}/ω = β_{n}

The load term can be written as follows:

 p(t)=\frac{4p_{0}}{\pi } \sum\limits_{n=1,3,5,}^{\infty }\frac{1}{n} \sin (n\bar{\omega }_{1}t )  for n = 1, 3, 5, etc.

= 0       for n = 0, 2, 4,etc

The  n^{th} term of the steady state response is of the form:

x_{n}=\frac{4p_{0}}{n\pi } \left\lgroup\frac{1}{k} \right\rgroup \frac{\sin (n\bar{\omega }_{1}t )}{1-\beta ^{2}_{n} }

Hence, the steady state response is given by

 x(t)=\sum\limits_{n=1,3,5}^{\infty }\frac{4p_{0}}{k\pi } \frac{1}{n} \frac{\sin (n\bar{\omega }_{1}t )}{\left\lgroup1-\left\lgroup\frac{n\bar{\omega }_{1} }{\omega } \right\rgroup ^{2} \right\rgroup }

Let us plot the amplitude of each harmonic term of load as well as displacement versus frequency.

p_{n}=\frac{4p_{0}}{n\pi }  or \frac{p_{n}}{p_{0}} =\frac{4}{n\pi }

or \frac{p_{n}}{p_{0}}\frac{\pi}{4 }=\frac{1}{n} where n = 1, 3, 5, etc.

= 0   n = 0, 2, 4, etc.

Its plot is shown in Figure 4.5(a).
Similarly, the amplitude of each harmonic of the response term can be plotted as follows:

\frac{x_{n}}{\frac{p_{0}}{k} } =\frac{4}{n\pi \left\lgroup1-\left\lgroup\frac{n\bar{\omega }_{1} }{\omega } \right\rgroup^{2} \right\rgroup }    for n = 1, 3, 5

= 0                      for n = 0, 2, 4, 6

Given ϖ_{1}/ω = ¼

∴        \frac{x_{n}}{\frac{p_{0}}{k} } =\frac{4}{n\pi \left\lgroup1-\left\lgroup\frac{n}{4} \right\rgroup^{2} \right\rgroup } for n = odd

Its plot is shown in Figure 4.5(b).