Difference between revisions of "Lab 9 TF EIM"
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#Construct the circuit shown below. | #Construct the circuit shown below. | ||
#Use a 1 kHz sine wave generator to drive the circuit so <math>V_a = V_0 cos(2 \pi \nu t)</math> where <math>V_0 = 0.1</math> V and <math> \nu</math> = 1kHz. (20 pnts) | #Use a 1 kHz sine wave generator to drive the circuit so <math>V_a = V_0 cos(2 \pi \nu t)</math> where <math>V_0 = 0.1</math> V and <math> \nu</math> = 1kHz. (20 pnts) | ||
| − | #Based on your observations using a | + | #Based on your observations using a oscilloscope, sketch the voltage at points A & B as a function of time. |
#Do another sketch for<math> V_0</math> = 1.0 V and another for 10.0 V. (20 pnts) | #Do another sketch for<math> V_0</math> = 1.0 V and another for 10.0 V. (20 pnts) | ||
Revision as of 03:49, 17 February 2011
Lab 9: Diode Circuits
Clipping Circuit
- Construct the circuit shown below.
- Use a 1 kHz sine wave generator to drive the circuit so where V and = 1kHz. (20 pnts)
- Based on your observations using a oscilloscope, sketch the voltage at points A & B as a function of time.
- Do another sketch for = 1.0 V and another for 10.0 V. (20 pnts)
Differentiating Circuit with clipping
- Construct the circuit below.
- Select and such that the current from the +5V DC source is 1.0 mA and the DC voltage at is 3 V.
- Select a capacitor to form a differentiating circuit for the pulse from the signal generator. Hint: .
- plot and as a function of time using your scope observations. (20 pnts)
- Now add the diode circuit from part 1 to prevent V_B from rising above +5 V.
- plot and as a function of time with the diode circuit you added using your scope observations. (20 pnts)
Questions
- Explain your results in parts 1 & 2 in terms of the diode turn-on voltage. (20 pnts)