There's a whole lot of weird quantum physics level stuff controlling the interactions between the three terminals. Don't base your understanding of a transistor's operation on that model (and definitely don't try to replicate it on a breadboard, it won't work). The diode representation is a good place to start, but it's far from accurate. The diode connecting base to emitter is the important one here it matches the direction of the arrow on the schematic symbol, and shows you which way current is intended to flow through the transistor. By narrowing our focus down - getting a solid understanding of the NPN - it'll be easier to understand the PNP (or MOSFETS, even) by comparing how it differs from the NPN. We'll turn our focus even sharper by limiting our early discussion to the NPN. Digging even deeper into transistor types, there are actually two versions of the BJT: NPN and PNP. In this tutorial we'll focus on the BJT, because it's slightly easier to understand. There are two types of basic transistor out there: bi-polar junction (BJT) and metal-oxide field-effect (MOSFET).
Symbols, Pins, and Construction - Explaining the differences between the transistor's three pins.
#Power transistor case series
This tutorial is split into a series of sections, covering: We won't dig too deeply into semiconductor physics or equivalent models, but we'll get deep enough into the subject that you'll understand how a transistor can be used as either a switch or amplifier. Covered In This TutorialĪfter reading through this tutorial, we want you to have a broad understanding of how transistors work. In quantities of thousands, millions, and even billions, transistors are interconnected and embedded into tiny chips to create computer memories, microprocessors, and other complex ICs. In small, discrete quantities, transistors can be used to create simple electronic switches, digital logic, and signal amplifying circuits.
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