Experiment 1 OperationalAmplifiers Introduction: This lab studies some of the basic uses of op amps. Because the main use of the op amp is as an amplifier, the three most common configurations will be studied. These include the inverting, non-inverting, and differential amplifier circuits. The lab will also investigate powering an op-amp from a single supply. Equipment Used: Type Oscilloscope Function Generator DC Power Supply Digital Multi Meter Model HP123 Serial No. Calibration Date 123456 07-11-10 Parts Used: QTY Component 1 1 1 1 1 1 1 Value Resistor Resistor Resistor Resistor Resistor Resistor Op-amp Type 10K 100K 33K 1K 3.3M 1.5M Carbon, +/-5% Carbon, +/-5% Carbon, +/-5% Carbon, +/-5% Carbon, +/-5% Carbon, +/-5% LF411 Software Used: Pspice MS Office 2010 Released Version: 16.0.0.s001 Theory: The LM741 Op amps have eight terminals, but we will only examine five of them: the VS+ , VS-, inverting input (V- ), non-inverting input (V+), and output (Vout ). The VS+ and VSare the positive and negative power supplies. The output voltage cannot be greater than the positive power supply nor can it be less than the negative power supply. In an ideal op amp, no current flows into the inverting and non-inverting inputs, although current can flow out of the input-controlled output. There is also no voltage difference between the inputs. One of these inputs cannot have its voltage change without the other input either increasing or decreasing in voltage to match. This ensures linear operation and keeps the output at the same voltage. This equilibrium is maintained by negative feedback through a feedback loop. Feedback loops direct the output voltage back to the inverting input. This negative feedback drives the circuit back to equilibrium in a manner specific to the circuit configuration. Procedure: Part 1: Measuring Offset Voltage Constructed the following circuit and our Vo was measured to be 0.78mV Graph from Pspice Simulation We then constructed the following circuit and measured Vo again. R1 was set to 33kΩ ohm and R2 was set to 3.3MΩ. Our measured result was Vo=0.259V Graph from Pspice Simulation Part 2: Inverting Gain Amplifier Constructed the following circuit. Using the Pre-Lab to obtain a -10 Gain. We let R2=100kΩ and R1=1KΩ Graph from Pspice Simulation Oscilloscope reading of -10 gain w/ phase shift. Frequency(khZ) Vi Vo 20dB Gain 1 0.098 0.98 20.00 10 0.098 0.96 19.82 30 0.098 0.92 19.45 35 0.098 0.88 19.07 40 0.098 0.88 19.07 45 0.098 0.86 18.87 50 0.098 0.84 18.66 60 0.098 0.8 18.24 70 0.098 0.72 17.32 80 0.1 0.7 16.9 90 0.102 0.66 16.22 100 0.102 0.6 15.39 120 0.102 0.56 14.79 Oscilloscope reading of -100 gain w/ phase shift. Frequency(khZ) Vi Vo 20dB Gain 1 0.098 9.6 39.82 5 0.098 8.4 38.66 10 0.098 6.4 36.30 15 0.098 4.8 33.80 20 0.098 4.0 32.22 25 0.098 3.2 30.28 30 0.102 2.8 28.77 50 0.102 1.6 23.91 60 0.102 1.36 22.50 75 0.102 1.04 20.17 90 0.102 0.88 18.72 100 0.102 0.8 17.89 120 0.102 0.68 16.48 Part 3: Non-inverting Gain Amplifier Constructed the following circuit. Using pre-lab equations obtain a gain of 1. Let R1= 1.53 M ohm and R2=1K ohm. Graph from Pspice Simulation Oscilloscope reading of 1 gain. Oscilloscope reading of 100 gain. Conclusion: In this lab we learned based on the experiment’s results,using a specific circuit, collecting and measuring data, a summing amplifier with two inputs was built, and the group has established a better understanding on how an amplifier operates. We were able to see our Vout remains pretty consistent at low frequencies and then dives at around 35kHz. The similarities between the inverting op-amp and non inverting op amp were pretty striking. We expected them to be completely different but they were very similar. This laboratory gave us opportunity to see working amplifiers and prove the theoretical formulas for their gains and output voltages. In this lab, we also experienced building circuits for inverting, non-inverting and summing amplifiers and got basic understanding by analyzing their output signals with the help of oscilloscope and multimeter
