Portland Community College | Portland, Oregon

The focus of this term is on operational amplifier characteristics and applications.  The laboratory component includes applications such as waveform generator circuits, filters, and instrumentation amplifiers.

1. Apply op-amps fundamentals in design and analysis of op-amps applications.

2. Apply op-amps fundamentals and computer tools in project design, evaluation, and analysis.

Assessment methods are to be determined by the instructor.  Typically, in class exams and quizzes, and homework assignments will be used.  Lab work is typically assessed by a lab notebook, formal lab reports, performance of experiments, and possibly a lab exam.

1.      Discrete transistor differential amplifier biasing and amplification. 

2.      Ideal operational amplifier, inverting and non-inverting amplifier configurations.  Biasing and offset currents, and offset voltages. Feedback theory, and negative feedback in op-amp circuits. 

3.      Frequency response, gain-bandwidth product, slew rate, compensation and stability.  Op-amp specifications. 

4.      Applications include: voltage summation, subtraction, scaling, voltage and current sources, waveshaping, integration, and differentiation.

5.   Op-amp oscillators and the Barkhausen criterion.  Oscillator types include: RC-phase shift, Wien bridge, Colpitts, and Hartley.         

6.   Active filters concepts and design, including low pass, high pass, and bandpass types. 

7.   Voltage comparators, Schmitt triggers, and relaxation oscillators, clippers, clampers, rectifiers, and other applications as time permits.