Question 4.4: Determine an expression for steady state response of an unda...
Determine an expression for steady state response of an undamped SDOF system subjected to a square pulse with ω = 4 ϖ_{1} in exponential form.
Let us write the expression for the steady state response of SDOF system as
given in Equations 4.10(a) and 4.10(b).
m\ddot{x} (t)+c\dot{x} (t)+kx(t)=p(t)=e^{i\bar{\omega }t } (4.10)
x(t)=H(\bar{\omega } )p(t)
or, x(t)=H(\bar{\omega } )C_{n}e^{i\bar{\omega } t}
where, H(\bar{\omega } )=\frac{1}{k(1-\beta ^{2}+i2\beta \xi )}
For an undamped system, ξ = 0,
∴ H(\bar{\omega } )=\frac{1}{k(1-\beta ^{2})} =\frac{1}{k\left[1-\left\lgroup\frac{n\bar{\omega }_{1} }{\omega } \right\rgroup^{2} \right] }
or, H(\bar{\omega } )=\frac{1}{k\left[1-\left\lgroup\frac{n}{4} \right\rgroup^{2} \right] }
Also, derived earlier, C_{n}=0 for n even
C_{n}=\frac{-2p_{0}i}{n\pi } for n odd
∴ n^{th} term of response can be written as x_{n}=H(ϖ) C_{n}
or, x_{n}=\frac{-i2p_{0}}{n\pi k\left[1-\left\lgroup\frac{n}{4} \right\rgroup^{2} \right] } for n odd
= 0 for n even
∴ \left|x_{n}\right| =\left|\frac{2p_{0}/\pi k}{n\left[1-\left\lgroup\frac{n}{4} \right\rgroup^{2} \right] } \right| for n odd
Alternatively, this can be re-written as follows:
\frac{x_{n}\pi /2}{p_{0}/k} =\frac{1}{n\left[1-\left\lgroup\frac{n}{4} \right\rgroup^{2} \right] } =\alpha for n odd
This can be plotted as shown in Figure 4.7.
