It’s about as likely that the transistor is attached to a pin that sends an interrupt to the processor and it then applies a soft mute as it is the transistor is attached to a flip flop or register that toggles the mic getting power physically.
My guess would be it’s controlled by software rather than directly by the hardware because then they can do whatever they want with the button via firmware or software updates. This includes nefarious stuff like a fake mute mode, or more innocent stuff like special behaviour on a long press vs short press.
I don’t understand what any of that has to do with this conversation.
Well, you claim that transistors can be controlled by software, and I claim that it is no more capable to run software than a mechanical switch.
It’s about as likely that the transistor is attached to a pin that sends an interrupt to the processor and it then applies a soft mute as it is the transistor is attached to a flip flop or register that toggles the mic getting power physically.
My guess would be it’s controlled by software rather than directly by the hardware because then they can do whatever they want with the button via firmware or software updates. This includes nefarious stuff like a fake mute mode, or more innocent stuff like special behaviour on a long press vs short press.
You could just connect the switch to an input pin on the processor. I don’t see how a transistor makes this scenario more likely.
I don’t know why you keep saying this so let me try for the third time:
A transistor does not run software, software runs transistors.
Please tell me. How exactly does software “run” a transistor?
The software is what decides when to send the signal to switch them on and off.
Now tell me, how does the software communicate with the transistor? Wifi? Bluetooth?
There is no “communication”. Transistors don’t have that capacity, they’re just switches.
Heh