Circuits and Electronics

Employ simple lumped circuit models for resistors, sources, inductors, capacitors, and transistors in circuits.

Analyze circuits made up of linear lumped elements. Specifically, analyze circuits containing resistors and independent sources using techniques such as the node method, superposition and the Thevenin method.

Employ Boolean algebra to describe the function of logic circuits.

Design circuits which represent digital logic expressions. Specifically, design a gate-level digital circuit to implement a given Boolean function.

Check static discipline constraints in circuits. For example, determine if the circuit representing a gate provides adequate noise margins.

Determine the output produced by a circuit for a given set of inputs using the switch resistor model of a MOSFET.

Perform a small-signal analysis of an amplifier using small signal models for the circuit elements.

Calculate the time behavior of first order and second order circuits containing resistors, capacitors and inductors.

Calculate the frequency response of circuits containing resistors, capacitors and inductors.

Construct simple gates, amplifiers, or filters in the laboratory.

Determine in the laboratory the time-domain and frequency-domain behavior of an RLC circuit.

Use operational amplifier models in circuits which employ negative feedback.

Use complex impedances to determine the frequency response of circuits.

Determine the power dissipation in digital gates and employ CMOS technology to reduce static power losses.

Predict how a given circuit will affect an audio signal in the laboratory given the frequency response of the circuit.

Design, build and test an audio playback system which includes both analog and digital components.