EXPERIMENTAL PROCEDURE 1. FINDING THE TRANSFER FUNCTIONS a) Take the mass of the block is M(kilogram=Newton-second?/meter), the spring constant is K (Newton/meter), the coefficient of viscous friction is fv(Newton-second/meter), distance taken in time is x(t)(meter) and force used in the system is f(t)(Newton). Write the transfer functions for figure 1.1, and figure 1.2. b) Accept that the M=2 kg, K=1 N/m, fv=1 N-s/m and find the transfer function according to those NBU x(t) values. x(t) f(t) → f(t) K Figure 1.1 x(t) f(t) M Figure 1.2
EXPERIMENTAL PROCEDURE 1. FINDING THE TRANSFER FUNCTIONS a) Take the mass of the block is M(kilogram=Newton-second?/meter), the spring constant is K (Newton/meter), the coefficient of viscous friction is fv(Newton-second/meter), distance taken in time is x(t)(meter) and force used in the system is f(t)(Newton). Write the transfer functions for figure 1.1, and figure 1.2. b) Accept that the M=2 kg, K=1 N/m, fv=1 N-s/m and find the transfer function according to those NBU x(t) values. x(t) f(t) → f(t) K Figure 1.1 x(t) f(t) M Figure 1.2
Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN:9780133923605
Author:Robert L. Boylestad
Publisher:Robert L. Boylestad
Chapter1: Introduction
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Transcribed Image Text:EXPERIMENTAL PROCEDURE
1. FINDING THE TRANSFER FUNCTIONS
a) Take the mass of the block is M(kilogram=Newton-second?/meter), the spring constant is K
(Newton/meter), the coefficient of viscous friction is fv(Newton-second/meter), distance taken
in time is x(t)(meter) and force used in the system is f(t)(Newton). Write the transfer functions
for figure 1.1, and figure 1.2.
b) Accept that the M=2 kg, K=1 N/m, fv=1 N-s/m and find the transfer function according to those
NBU
x(t)
values.
x(t)
f(t)
→ f(t)
K
Figure 1.1
x(t)
f(t)
M
Figure 1.2
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