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In-Class Problems 1.Sketch the following functions: a) x(t) = 3sin(40  t) for 0≤ t ≤ 0.2 sec b) z(t) = 10e -4t for 0≤ t ≤0.5 sec 2.What is ? 3.What is.

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Presentation on theme: "In-Class Problems 1.Sketch the following functions: a) x(t) = 3sin(40  t) for 0≤ t ≤ 0.2 sec b) z(t) = 10e -4t for 0≤ t ≤0.5 sec 2.What is ? 3.What is."— Presentation transcript:

1 In-Class Problems 1.Sketch the following functions: a) x(t) = 3sin(40  t) for 0≤ t ≤ 0.2 sec b) z(t) = 10e -4t for 0≤ t ≤0.5 sec 2.What is ? 3.What is ? 4.What is ?

2 Capacitor-Resistor Circuits In-class activity: In pairs build this circuit in Multisim. Look at the voltage across the capacitor on the oscilloscope. Describe what you see when the switch moves between positions (let the switch stay in each position until the capacitor voltage stops changing).

3 Discharge of a Capacitor Through a Resistor In the following circuit, when the switch moves from the battery to the wire connected to ground, the voltage across the capacitor is v c (t) = V s e -t/RC VsVs - vcvc

4 Class Activity What are the units of RC in v c (t) = V s e -t/RC ? Since v c (t) = V s e -t/RC and, what is i(t) in terms of V s, R and C? What do v c (t) and i(t) look like on a graph?

5 Step Response: RC Time Constants Now, what happens when the switch moves the other way? The response of the capacitor voltage will be to charge up to the supply voltage. VsVs

6 V c Response to Constant Voltage V s The voltage across the capacitor will rise and asymptotically approach V s How can we describe this mathematically?

7 Kirchhoff’s voltage loop law Ohm’s law across resistor Substituting for V R gives Analysis of RC Circuits VsVs vcvc

8 Substitute in for i From previous page Analysis of RC Circuits VsVs vcvc

9 The equation is called a differential equation. The solution is of the form: where is defined as the time constant  = the circuit time constant, in seconds if and only if C= the total (connected) capacitance Farads R= the total (connected) resistance Ohms

10 Team Activity Substitute into the equation to show that LHS = RHS

11 Show that when t is 5 times the time constant,, the capacitor voltage is 99.33% of the peak voltage. Team Activity

12 Kirchhoff’s voltage loop law ? Ohm’s law across resistor? Substituting for V R gives? Team Activity – Discharge Process

13 From previous activity the equation Team Activity and show that LHS = RHS Substitute into the above equation

14 Rectangular Wave If you repeatedly switch between the battery and the short you are effectively applying a rectangular time pulse to the RC circuit.

15 Rectangular Wave Response The voltage across the capacitor will behave as below in response to such a wave:

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