Hi Laplace - with all respect, a simple experiment (hardware or simulation) can show that this assertion is false!
Not so, if the device were connect to nothing, then no input current would be present.
It is the current source that is supplying the Vbe voltage. It is the Vbe that is controlling the current according to the physics of the depletion region and the bulk resistance of the base-emitter diode.
We are not talking about design, we are talking about how a BJT works. Vbe does control both the base and collector currents in a BJT. When designing circuts, we try to minimize the exponential response of Vbe by swamping out its effect with lots of resistance. However, the transistor still follows its Vbe.
Even during the design of BJT stages the (assumed) voltage VBE plays an important role.
If my statement were taken in isolation then your objection could have merit. However, the assertion was in the context of base current being set by a current source (or a biasing network that approximates a current source). In that context, the exact value of Vbe is not relevant although it will have some value corresponding to the exact current being driven through the diode of the base-emitter junction.
I aver that at the same temperature, the base current, Vbe, and collector current of a BJT will be the same in a circuit as it would be if the transistor were isolated from the circuit and run only on voltage sources.
But again you misunderstand. I never claimed there was no connection. This is where the magic happens.
That particular stance only goes so far. Transistors do not work just by themselves, they eventually end up being used in a circuit. And one objective of good circuit design is to make the value of Vbe irrelevant.
No doubt true, but the value of Vbe is irrelevant, and the base current as set by the bias network controls the operation of the transistor in-circuit.
Instead of "irrelevant" I would prefer "less important". OK?
Perhaps "irrelevant" is too strong a word, but it was chosen to emphasize disregard for the nonsense that Vbe controls the base current when the base is driven by a current source. Nevertheless, biasing networks are seldom designed as perfect current sources so that voltage drift in the generated Vbe will thereby affect the base current. Revise to say that the exact value of Vbe is irrelevant, but the drift range must be accounted for.
It is just the simple realization that when the base is driven with a current source, Vbe does not control the current. It is the current source that controls the current which flows while Vbe becomes whatever value is necessary to reflect that exact current plus other drift factors. Once the transistor has been biased at a particular current, it can be modeled as a transconductance device for Vbe over a 10mV range at the bias point (or for a wider range if one is willing to accept greater distortion). Even so it is not the value of Vbe that is relevant, rather it is ΔVbe at the bias point that is the quantity of interest.
Which current are you speaking of (Ib or Ic)? Vbe does not control....?
So you think that it is NOT the Vbe value at the bias point that is of interest?
I never stated that "base current from a current generator controls collector current." Whereas your statement, "Vbe does control the base current according to the physics of the transistor {#30}" is nonsense when the base is driven by a current source because the current source will increase the applied voltage to any level necessary to force the specified current to flow into the base. The applied voltage is equal to Vbe at the base current controlled by the current source. This is why base current controls Vbe, and Vbe controls collector current as I have stated.
