Bioinstrumentation Circuit And Measurement Principles
BME 30500

Fall 2013
BME305 homework, Lecture 12, sdomain analysis, Name_
In lecture 11, we learned convolution with an impulse response, y(t)=x(t)*h(t) for timedomain analysis of a
linear system. In the s domain, such convolution becomes a direct product, i.e., for
Y(s)=X(
Bioinstrumentation Circuit And Measurement Principles
BME 30500

Fall 2013
BME305, homework for Lecture 8 2nd order circuit, Name_
1. A parallel RLC circuit is shown below. R = 1000 , C = 0.167 F, and L = 1.0H. There is an initial
voltage of 50.0 V on the capacitor. The switch is closed at t=0.
a. Compute and 0. Is the circuit u
Bioinstrumentation Circuit And Measurement Principles
BME 30500

Fall 2013
BME305, homework for Lecture 5 Op Amp, Name_ Score_
1 Find the Thevenin equivalent of the following circuit to the left of nodes A & B and then find v2 for RL=1 k, 10
k and . (20 pts)
2 Find the Thevenin equivalent and v2 for RL=1 k, 10 k and for the circ
Bioinstrumentation Circuit And Measurement Principles
BME 30500

Fall 2013
BME305, homework for Lecture 4, RC circuit, Name_
At t=0, just before the switch is closed in the following circuit, vC = 100 V.
(i)
(ii)
(iii)
(20 pts) Obtain the transient current and charge. Hint: q(t)=CvC(t).
(10 pts) Obtain the power and energy in t
Bioinstrumentation Circuit And Measurement Principles
BME 30500

Fall 2013
BME305, homework for Lecture 3, Name _, Score _
For the circuit below, (i) Calculate the shortcircuit current, isc. (ii) Calculate the opencircuit voltage, Voc. (iii)
Calculate the Thevenin equivalent resistance, RTh. (iv) Draw the Thevenin equivalent c
Bioinstrumentation Circuit And Measurement Principles
BME 30500

Winter 2015
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