You're welcome. Glad that you liked my videos. Here are a few related circuit examples: Negative Inductance Design kzbin.info/www/bejne/fXfCfqiklLKer9E Converting Capacitance to Inductance with Op Amp Circulator Amplifier kzbin.info/www/bejne/rZaseXpqaqxphsk Impedance Converter Design with Op Amp (Gyrator) kzbin.info/www/bejne/oIHYlZtvrtZ3fpY , Active Inductor with Op Amps kzbin.info/www/bejne/bHq8q2eflsZja8U I hope these examples are interesting as well.

@debrainwasher Thanks for the comment and sharing your thoughts. Glad that you liked this Impedance Converter Analog Circuit Design with Op Amp video. I would not say Analog circuits are outdated at all. While digital circuits are everywhere, there are still considerable applications that require analog circuit design including mixed signal design, sensor interfacing, data converters, extremely low power circuits, Neuromorphic computing that aims to mimic the structure and operation of the human brain, using artificial neurons and synapses to process information (for example neural processors used for artificial intelligence). For more example see the following two KZbin playlist in my channel: Analog and Op Amp Circuit Design Videos kzbin.info/aero/PLrwXF7N522y4c7c-8KBjrwd7IyaZfWxyt Digital Circuits and Digital Signal Processing kzbin.info/aero/PLrwXF7N522y6cSKr0FmEPP_zQl011VvLr

@@STEMprof I agree, there are applications, where Opamp-Circuits are still useful - particularly in signal-preprocessing. I did and still do many analog-designs. In many cases, particularly, when enough ressources are present, DSP is simply the better choice, since there are no component tolerances, temperature-problems, power losses, or even RFI-, or high voltage issues. A couple of years ago, I designed an adaptive, active RFI mains-power filter (230VAC) with power factor correction for a customer. I used two class-D H-Bridges with power-FETs and a large electrolytic capacitor as a reactance - controllable as a capacitance, inductance - or both. The transfer function was created in real time by Hanning-windowed FFT and IFFT. It worked quite well, but above ca. 170kHz, the bandwidth of the power-circuit was exhausted, while targeted switching noise went a magnitude higher. Therefore, the project has been abandoned. Today, contemporary GaN-FET and fast FPGA could probably do the job.

Well said. Thanks for sharing your thoughts and observations. I hope you enjoy this channel.

You're welcome. Glad that you liked this video and Thanks for sharing your thoughts. The LM741 Op Amp is a legend among operational amplifiers. It has been taught in circuit design courses since early 90s. With that said, I have listed a few more recent well-designed op amps for gain-bandwidth product up to 8 GHz (from Texas Instruments and Analog Devices) in the video kzbin.info/www/bejne/pardZ5-KfMlljtE that focuses on Op Amp Amplifier with -25 to 55 dB Attenuation-Gain range. I hope it is useful.

Thanks for sharing your interesting experience 👍. What was the result of performance comparison? And I hope you also like the following two related videos: Negative Inductance Design kzbin.info/www/bejne/fXfCfqiklLKer9E And Floating Inductance with Op Amp Circulator Amplifier kzbin.info/www/bejne/rZaseXpqaqxphsk