In the A Term, we learned commonly used sensors such as resistive temperature sensors, capacitive touch sensors, and inductive motion sensors and actuators. In the meantime, numerous applications are presented to motivate coverage of fundamental operating principles of circuit elements such as resistors, capacitors, and inductors; model the signals produced by these sensors; and analyze the circuits and systems used to amplify and process these signals. After a review of Kirchhoff ‘s current and voltage laws, fundamental analysis techniques such as Thevenin and Norton’s theorems and the superposition principle are used to model and analyze sensors, circuits, and systems. Concepts from analysis of linear, time-invariant continuous-time signals and systems are introduced as necessary, including Fourier series and characterization of systems such as filters in both the frequency domain (bandwidth, transfer function) and time-domain (rise time, step response). Capacitance, inductance, and mutual inductance are explored as energy storage elements, including consideration of resonance and energy losses in power systems.
We had two fantastic guests close to the end of the term. First Mike Coln from ADI shared his experience on biosensors and explained to us the circuits which help to extract information from biosensors. Our second guest was Prof. Bitar, who demonstrated the filters’ effect on audio application with an unforgettable show.