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Download Lab02-GL Rev. 2 - geek @ EE @ NMT
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Transcript
New Mexico Tech EE321L - Analog Electronics Fall 2013 Laboratory Exercise 2 Non-ideal DC characteristics of Operational Amplifiers (and a little AC) Pre-Lab 1. Find the LM741 and LF411 data-sheets, for example on www.digikey.com. 2. Derive the relationship between offset voltage and output voltage for non-inverting amplifiers. 3. Look up voltage follower circuit and buffer circuit. What is the difference? 4. Research how to use the offset nulling circuitry on the LM741 and LF411 op-amps. 5. Design the circuit in step 8. Input Offset Voltage 1. Using a LM 741 op-amp, build an inverting voltage amplifier with a gain of approximately 1000, using a feedback resistor of 100 kΩ. Measure the relationship between the output and the input for several positive and negative input voltages. You may use a voltage divider to create small voltages or a very-low frequency square-wave from the function generator. 2. Verify that the measured gain (the slope) is close to the designed value. 3. What is the output for a zero input voltage? What does that imply for the offset voltage? How does the inferred offset voltages compare with the data-sheet? You may also wish to ask other students for their measured offset voltage values and include those in your report to get a better feel for the variability of the offset voltage. 4. Attach the nulling circuitry, describe how to use it to null the output, and show that you can null the offset voltage. 5. At the end of the lab (To ensure you make it though the bias current and slew rate parts) repeat steps 1-3 for the LF411. Compare the LM741 and LF411’s offset voltages? Input Bias Current 6. Build a voltage follower (buffer) with the LM741, but instead of a short between the output and negative input, insert a large resistor (experiment in the 1MΩ to 30 MΩ range.) 7. Ground the input, and measure the output. What does this imply for the bias current, and the direction of the bias current? Make sure your resistor is large enough that the output reflects mostly the bias current and less the offset voltage. 8. Design a circuit, which eliminates the bias current (assume the negative input current you just measured is the bias current.) 9. What is the residual voltage? What does this imply about the offset current? New Mexico Tech EE321L - Analog Electronics Fall 2013 Slew Rate 10. Build an inverting amplifier with a gain of 10 using the LM741. 11. Apply a sinusoidal or square-wave input of high enough frequency and amplitude that the signal becomes triangular. What is the slew rate of the LM 741? 12. Repeat steps 10 and 11 using the LF411 instead. Compare the two amplifiers and compare with the datasheets. Note: Observation is not always a good substitution for knowledge. SVAQ GUR OBYQ YRGGREF SBE RKGEN CBVAGF
