Excellent, please bring more interesting circuit. Now when eevblog is mostly some general electronic talk i really miss good circuit analysis. I know it wont get you a big audience but i think it's a niche that will definitely get you a steady group of fans 😊

Liked your video before watching it

Great content I'm learning so much from your videos keep the good work and thank you for sharing

Really great, the circuits but LTSPICE trick too. Thanks

Foarte tare ! Excellent explained and presented !

Great video. Maybe it's worth to mention that the creepage and clearance distances you're talking about are for mains vs secundairy voltage. They are much lower and forgiving between (two) different secundairy voltages.

as always Very Nice!

Really, interesting video.

Great tutorials! I wonder which is the simulator program you use. Is it free? Is any free one that you recommend for this kind of simple circuit analysis? Thanks a lot!

i have a question! i´m working on a final proyect about loads dc, and after see all topics about MOSFETs i wonder which schematic configuration would you recommend for a load with a power = 136W ???. I´m using four IRLZ44N in paralalel to handle that power and a btj to handle the gate of each one making a reduction voltage.

Hello again Fesz. Thank-you for another interesting and challenging video! I’ll add a few comment to express my perspective. First circuit (Q7, Q8, and Q9). There is feedback from the output to the resistor divider. Therefore, we cannot fully saturate at the output of Q9 because as the load is pulled down, the feedback reduces the drive to the bases of (Q8 and Q9). On the other hand, when we apply 0.4V to Q7 in order to cut the transistors off, current flows through the load and into the resistor divider, which prevents the output from reaching VCC. Second circuit (Q24, Q25, and Q26). Without the feedback and the reduction of base drive, the output can be saturated and can also come up to VCC. How to explain the differences in power dissipation during the linear regions? In the first circuit, during the transition from on to off, the emitter voltages of the middle and top transistors are defined by the base voltages as those base voltages rise with decreasing current. Because these base voltages come from a single resistor divider, which is driven by the load voltage they are in the desired proportion and the power dissipation in the 3 transistors is relatively equal. For the same transition in the second circuit, the collector voltage of the bottom transistor comes up first, followed by the collector voltages of the middle and top transistors. The power dissipation is therefore larger in the bottom transistor, less in the middle transistor, and much less again in the top transistor. How this is explained by the use of separate voltage dividers driven from the supply is not clear to me.

Instead of using bjt transistors, is the series explanation same for MOSFETs?

Ooo, sooo good! Thank you!

i think i have a little more complicated sircuit. input is 3700vac rms and IGBTs are rated for 1200v. i cant do that resistor devider, do you think that i can hook up every base of the transistors to a seperate controll sircuit?

why is playlist in order 3-2-1 😢

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