In my undergrad studies, I never worked with designing or working with discrete MOSFET circuits.
When it came to CMOS, it was always simulation based study. As a result, it never gave the physical feel of MOSFETS.
In my quest to satiate my anxiety to design with discrete mosfets, a few years ago, I came across following course material from the Worcester Polytechnic, MA : ECE4902 - Analog IC Design - Joh McNeil.
What was different in this course was that, it was accompanied with labs, wherein a CMOS op-amp is designed/analysed using discrete components. Well not exactly discrete MOSFETS, but rather using a MOSFET array chip - CD4007, which is also called as hex inverter. It consists of 3 pmos-nmos pairs within a DIP package and thus usable on breadboard.
In excitement, I went ahead and ordered a couple of CD4007 IC's, from a little know website "onlinetps".
When it came to CMOS, it was always simulation based study. As a result, it never gave the physical feel of MOSFETS.
In my quest to satiate my anxiety to design with discrete mosfets, a few years ago, I came across following course material from the Worcester Polytechnic, MA : ECE4902 - Analog IC Design - Joh McNeil.
What was different in this course was that, it was accompanied with labs, wherein a CMOS op-amp is designed/analysed using discrete components. Well not exactly discrete MOSFETS, but rather using a MOSFET array chip - CD4007, which is also called as hex inverter. It consists of 3 pmos-nmos pairs within a DIP package and thus usable on breadboard.
In excitement, I went ahead and ordered a couple of CD4007 IC's, from a little know website "onlinetps".