Bipolar Junction Transistors

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(16ELA003 - Electronics) Engineering Fichas sobre Bipolar Junction Transistors, creado por Ben Evans el 18/04/2017.
Ben Evans
Fichas por Ben Evans, actualizado hace más de 1 año
Ben Evans
Creado por Ben Evans hace más de 7 años
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Pregunta Respuesta
What is a transistor? An active component, its an amplifier. It has an external power supply which it uses to generate gain
What happens to the base layer when a sufficient voltage is placed across it? Effectively disappears as it is so thin compared to the other layers
Applying KCL to a transistor gives what equation? I(E) = I(C)+ I(B)
What is another equation for I(C)? I(C) = I(C,majority) + I(CO)
What is I(CO)? Collector current measured with the emitter open, is termed the LEAKAGE current
What is the definition of "common base" configuration? The two voltage sources share the base terminal
In the cut-off region what state are the junctions? Both are fully REVERSE bias
In the saturation region what state are the junctions? Both are fully FORWARD bias
What is ⍺(DC)? ⍺(DC) = I(C) / I(E) It's the common base short circuit amplification factor Normally ranges from around 0.90 to 0.99, though the approximation is ⍺ = 1.
What is ⍺(AC)? ⍺(AC) = ΔI(C) / ΔI(E) The values of alpha are approximately equal for AC and DC
What is the definition of "common emitter" configuration? The two voltage sources share the emitter terminal
How does common emitter vary from common base? The output characteristic lines of I(C) are much more sloped, the effect of the source used for gain is much greater
What is β? β = I(C) / I(B) Its the common-emitter forward amplification factor Typically has a value between 50-400
What is β often listed as on transistor data sheets? h(fe)
How are ⍺ and β linked? β = ⍺ / (1 - ⍺) ⍺ = β / (β + 1)
What is the Quiescent point or 'Q' point? Refers to the DC biasing, so that the AC amplification occurs within the active region of the output characteristics
What two currents does β link together? I(C) = β * I(B)
What is the emitter current in a common emitter amplifier in terms of base current and β? I(E) = (1 + β) * I(B)
What is the definition of a "common collector amplifier"
What is the difference between common collector and common emitter? The output curves differ as I(E) = ⍺ * I(C)
What limits the curves in the active region? Transistors have a maximum power dissipation so I(C) * V(CE) must be less than that value
How to use derating info? It is used to calculate the max power when ambient air or case temperatures can't be met. As this value will be lower
What are load lines? They are used to graphically solve problems where a non-linear circuit element is connected to a linear one
What does a fixed bias transistor circuit look like?
What does a voltage divider bias transistor circuit look like?
What are the steps for finding bias voltages and currents? 1. Simplify circuit for DC analysis 2. Simplify input using Thevenin's theorem 3. Calculate base current 4. Infer collector current 5. Calculate V(CE) from the 'load line' equation
What is the assumption given for the voltage across the emitter resistor? It is one tenth of the supply voltage
What is the assumption made for the current through the potential divider and why is this assumption made? In order to maintain the bias, by maintaining I(B), the current through the potential divider must be greater than the base current. Say 10 times as an assumption
What is the problem with class A amplifiers? Even when not amplifying the active device and series resistor(s) consume power. The theoretical efficiency is 50% at best
What is linearity? The output increases exactly in proportion to the input. If this does not happen the signal is distorted, leading to harmonics.
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