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LARGE-SIGNAL BEHAVIOR OF BJTS Large-signal models in the forward-active region Effects of collector voltage in the forward-active region Ohmic and inverse.

Published byMadeline Hudson Modified over 8 years ago

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Presentation on theme: "LARGE-SIGNAL BEHAVIOR OF BJTS Large-signal models in the forward-active region Effects of collector voltage in the forward-active region Ohmic and inverse."— Presentation transcript:

1 LARGE-SIGNAL BEHAVIOR OF BJTS Large-signal models in the forward-active region Effects of collector voltage in the forward-active region Ohmic and inverse active regions Transistor breakdown voltages Dependence of transistor current gain on operation conditions (saturation)

2 Bipolar Junction Transistor (BJT) One diode...Why not another diode

3 Bipolar Junction Transistor (BJT) What happens when we combine them?

4 NPN Bipolar Junction Transistor BJT = Bipolar Junction Transistor Collector (C) Emitter (E) Base (B)

5 Carrier Transport in a BJT

6 BJT Band Diagram V bi + V cb V bi + V eb V eb > 0 Base Width (W) Emitter BaseCollector Forward-Active Region of Operation EfEf

7 BJT Current Equations Electrons and Holes recombine in the base region at a rate . Typically,  is limited by this recombination (looks like a saturated subthreshold MOSFET) No recombination Recombination Base Width (W)

8 Forward-Active Region of a BJT EmitterBaseCollector 0W Carrier Concentration E-B Depletion Region C-B Depletion Region n e0 e V BE /U T V BE > 0 (Forward Biased), V BC < 0 (Reversed Biased)

9 Forward-Active Region of a BJT EmitterBaseCollector 0W Carrier Concentration E-B Depletion Region C-B Depletion Region n e0 e V BE /U T I C = I C0 e I B = I C /  f V BE /U T d 2 n dx 2 + = 0 nnnn dn dx I C = q A D n W << L n

10 Gummel Plots 0.10.20.30.40.50.60.7 10 -12 10 -11 10 -10 10 -9 10 -8 10 -7 10 -6 10 -5 Base-Emitter Voltage (V) Currents Ic: n=1, Is = 5.52fA Ib: n=1.019, Is = 0.048fA

11 Gummel Plot:  depends on I c

12 Current gain changes Region II: Midcurrent region where  F is approximately constant Region III: High current region where  F decreases as i C increases Region I: Low current region where  F decreases as i C decreases

13 Large-Signal Modeling (sort of) Does not incorporate the Early effect

14 Reverse-Active Region of a BJT EmitterBaseCollector 0W Carrier Concentration E-B Depletion Region C-B Depletion Region n c0 e V BC /U T V BC > 0 (Forward Biased), V BE < 0 (Reversed Biased) I E = I E0 e I B = I C /  R V BC /U T

15 Ohmic Region of a BJT This region is often called saturation ^ Incorrectly EmitterBaseCollector 0W Carrier Concentration E-B Depletion Region C-B Depletion Region n e0 e V BE /U T n c0 e V BC /U T V BC > 0 (Forward Biased), V BE > 0 (Forward Biased)

16 Ebers-Moll Model of a BJT EmitterBaseCollector 0W Carrier Concentration E-B Depletion Region C-B Depletion Region n e0 e V BE /U T n c0 e V BC /U T I C = I C0 ( e - 1 ) - I E0 ( e - 1 ) = I C0 e ( ( e - (I E0 / I C0 ) e ) + I C0 - I E0 V BE /U T V BC /U T V B /U T -V E /U T -V c /U T

17 Ohmic and Active BJT Regions -V CE /U T I C = (I C0 - I E0 ) + I C0 e ( 1 - (I E0 /  R I C0 ) e ) V BE /U T 00.511.522.533.544.55 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 Collector voltage (V) Collector current (  A) V CE (sat)

18 Simplified Ohmic Model In ohmic, both junctions are forward biased and the impedance levels looking into the emitter or collector is very low. V BE (on)  0.6 to 0.7V and V CE (sat)  0.2V

19 TRANSISTOR BREAKDOWN VOLTAGES Common-Base Transistor Breakdown Characteristics

20 BJT Breakdown Characteristics

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