Common Base Amplifier - Theory and Basics (1/2)

Lol, it was funny. I have drawn an extra wire for the positive power supply line, because I was very skeptical that it is possible to use the inner wire of the coax cable for this purpose.

He helped me out a lot using his videos as a base

I guess I'll have to look at that some time after the common emitter configuration. Thanks for the suggestion!

It would be great.

pick a value of L that will result in a high impedance at the desired frequency of operation, so at that freq it will 'look' like an 'open circuit'

"the amp copies the signal that is on the emitter instead of amplifying it, Is that correct ?". Yes, that's correct. Applications for common base circuits are cascode amplifiers and emitter switched bipolar transistor which can be viewed as a level shifting circuit.

I think of it differently - in the Common Collector circuit, you "push" current into the base, and that base current gets multiplied by a large number, like 100. The collector and emitter currents are nearly the same - there is 100 times more collector current in the emitter than there is base current.
In Common Base circuit, you "pull" current from the emitter, but the emitter and collector currents are still nearly the same - the base current is still about 100 times lower than the emitter current you're pulling.
I haven't simulated this, but I believe the improved isolation essentially derives from the fact that you're shrinking the voltage drop on the collector - base capacitance. For the Common Collector case, you're intentionally driving a voltage on the base, and it is about 180 degrees out of phase with the output. Since i = Cdv/dt, the higher the frequency you go, the more current is driven through the CB capacitance.
Conversely, with the Common Base case, the AC base voltage is close to 0V, so you only have the collector voltage swing pulling current through that capacitance - you no longer an AC base voltage pulling in the opposite direction increasing that current even more.

@@Cynthia_Cantrell I tried it in a sim. You are right, the emitter and collector current are almost equal (difference is the very small base current ) The amount of base current is indeed pulled because it does almost makes no difference if I change the voltage divider. two times 100k or 2 times 100 ohm is a small difference in base current (in the uA's ) So thanks, I'm never to old to learn :-) edit: it is possible to get big differenced in current if you play around with the collector and emitter resistors. If they are far apart you get big DC offsets f.i 50 ohm collector and 1k emitter. That also causes a pretty big base current if you use 100 ohm in the voltage divider. Using 10k makes the basecurrent smaller but still a big DC offset. Enough to kill the 2n2222 in my sim (almost 50mA using 2x100 ohm)
For me it was to see if the base is "modulated" by the ac signal on the emitter resistor shifting the Vbe up and down and it worked as I expected. All 3 signals are in phase. Interesting, I now I have to take my trusty "the art of electronics" and look at the math.

@@pa4tim Glad you found it useful! In most applications we see current "pushed" into the base to make an inverter, for example. But that emitter diode doesn't know or care how the current got into it!
Tie the base to 3.3V with a suitable resistor, and the emitter to a logic output, and now you have a non-inverting level shifter that will go up to the transistor's Vce max - just tie the input of the device you're controlling to the collector - with an appropriate resistor to a high voltage rail, say 24 or 48V, for example. In this case current is "pulled" through the base when the logic output goes low, rather than being "pushed" in when the base is driven high (as happens with an inverter).
Sometimes it's helpful to imagine things "backwards."
Enjoy some "Art!" 🙂