chapter10sm - SOLUTIONS CHAPTER 10 10.1 For an npn...

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Unformatted text preview: SOLUTIONS CHAPTER 10 10.1 For an npn transistor with ' 19 3 10 DE N cm- = , ' 17 3 2 10 AB N cm- = , ' 16 3 5 10 DC N cm- = , 0.13 E W m = , and 0.15 B W m = under the bias conditions of 20 B I A = and 2.5 BC V V = - , find a) b) I C c) r d) g m e) ( ) BE C C f) C g) f co h) f T Note that band gap narrowing should be accounted for, and that both sides of the E-B junction are short. Let the area of the emitter junction be A E =2.5 10- 7 cm-2 and the area of the collector junction be A C =8 10-7 cm-2 . a) To find , we use Equation (9.43) and from Figure 2.25, * 50 g E meV = . Then * ' g E C nB E kT AB pE B N D W e N D W - = From Figure 3.11, we find D pE 3.8, and D nB 13 cm -2 /s. The widths are W E =0.13 m and W B =0.15 m. * ' 0.05 19 0.026 17 2.86 10 13 0.15 2 10 3.8 0.13 83 g E C nB E kT AB pE B N D W e N D W e -- = = = Anderson & Anderson 1 May 13, 2009 Chapter 10: Solutions b) C Since , C B I I = 83x20 1.7 . C I A mA = = c) r 6 0.026 1300 20 10 B kT r qI - = = = d) g m From Equation 10.15 83 64 1300 m g mS r = = = e) C For a BJT operating in the active mode, scEB jEB C C ? and we can approximate scBE C C 2245 . From Equation 10.30 for constant base doping, the stored charge capacitance is ( 29 ( 29 ( 29 ( 29 2 4 2 13 2 0.13 10 83 2.4 10 0.24 3 3 15 / 1300 B sc nB cm W C F pF D r cm s -- = = = = f) C The capacitance C is just the BC junction capacitance. This is not a one- sided junction, so the result is: Anderson & Anderson 2 May 13, 2009 Chapter 10: Solutions ( 29 ( 29 ( 29 ( 29 ( 29 ( 29 ( 29 ( 29 ( 29 ( 29 ( 29 1 2 1 19 14 17 3 16 3 2 7 2 17 16-14 2 1.6 10 11.8 8.85 10 / 2 10 5 10 8 10 2 2 10 5 10 0.83 2.5 2.5x10 0.025 A D jBC A D bi a q N N C C A N N V V F cm cm cm cm F pF ----- = = +- ? = ( +- - = = where we found the value of V biBC from ( 29 ' ' 17 16 2 2 10 2x10 5 10 ln 0.026ln 0.83 1.08 10 A D bi i N N kT V V q n = = = ? g) f co The cutoff frequency for this transistor is, from Equation (10.37), ( 29 ( 29 ( 29 13 14 1 1 462 2 2 1300 2.4 10 2.5 10 co be f MHz r C C F -- = = = + + h) f T From Equation (10.38), ( 29 ( 29 6 9 83 462 10 38 10 Hz 38GHz T DC co f f = = = = 10.2. For the transistor of Problem 10.1, plot i c i b as a function of frequency. What is the unity-gain frequency?...
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chapter10sm - SOLUTIONS CHAPTER 10 10.1 For an npn...

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