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Lecture 7 ANNOUNCEMENTS • MIDTERM #1 will be held in class on Thursday, October 11 • MIDTERM #2 will be held in class on Tuesday, November 13 OUTLINE • BJT Amplifiers (cont’d) – Biasing – Amplifier topologies – Common-emitter topology Reading: Chapter 5.1.2-5.3.1 EE105 Fall 2007 Lecture 7, Slide 1 Prof. Liu, UC Berkeley Biasing of BJT • Transistors must be biased because 1. They must operate in the active region, and 2. Their small-signal model parameters are set by the bias conditions. EE105 Fall 2007 Lecture 7, Slide 2 Prof. Liu, UC Berkeley DC Analysis vs. Small-Signal Analysis • Firstly, DC analysis is performed to determine the operating point and to obtain the small-signal model parameters. • Secondly, independent sources are set to zero and the small-signal model is used. EE105 Fall 2007 Lecture 7, Slide 3 Prof. Liu, UC Berkeley Simplified Notation • Hereafter, the voltage source that supplies power to the circuit is replaced by a horizontal bar labeled VCC, and input signal is simplified as one node labeled vin. EE105 Fall 2007 Lecture 7, Slide 4 Prof. Liu, UC Berkeley Example of Bad Biasing • The microphone is connected to the amplifier in an attempt to amplify the small output signal of the microphone. • Unfortunately, there is no DC bias current running through the transistor to set the transconductance. EE105 Fall 2007 Lecture 7, Slide 5 Prof. Liu, UC Berkeley Another Example of Bad Biasing • The base of the amplifier is connected to VCC, trying to establish a DC bias. • Unfortunately, the output signal produced by the microphone is shorted to the power supply. EE105 Fall 2007 Lecture 7, Slide 6 Prof. Liu, UC Berkeley Biasing with Base Resistor • Assuming a constant value for VBE, one can solve for both IB and IC and determine the terminal voltages of the transistor. • However, the bias point is sensitive to variations. EE105 Fall 2007 Lecture 7, Slide 7 Prof. Liu, UC Berkeley Improved Biasing: Resistive Divider • Using a resistive divider to set VBE, it is possible to produce an IC that is relatively insensitive to variations in , if the base current is small. EE105 Fall 2007 Lecture 7, Slide 8 Prof. Liu, UC Berkeley Accounting for Base Current • With a proper ratio of R1 to R2, IC can be relatively insensitive to . However, its exponential dependence on R1 // R2 makes it less useful. EE105 Fall 2007 Lecture 7, Slide 9 Prof. Liu, UC Berkeley Emitter Degeneration Biasing • RE helps to absorb the change in VX so that VBE stays relatively constant. • This bias technique is less sensitive to (if I1 >> IB) and VBE variations. EE105 Fall 2007 Lecture 7, Slide 10 Prof. Liu, UC Berkeley Bias Circuit Design Procedure 1. Choose a value of IC to provide the desired smallsignal model parameters: gm, r, etc. 2. Considering the variations in R1, R2, and VBE, choose a value for VRE. 3. With VRE chosen, and VBE calculated, Vx can be determined. 4. Select R1 and R2 to provide Vx. EE105 Fall 2007 Lecture 7, Slide 11 Prof. Liu, UC Berkeley Self-Biasing Technique • This bias technique utilizes the collector voltage to provide the necessary Vx and IB. • One important characteristic of this approach is that the collector has a higher potential than the base, thus guaranteeing active-mode operation of the BJT. EE105 Fall 2007 Lecture 7, Slide 12 Prof. Liu, UC Berkeley Self-Biasing Design Guidelines (1) RC RB (2) VBE VCC VBE (1) provides insensitivity to . (2) provides insensitivity to variation in VBE . EE105 Fall 2007 Lecture 7, Slide 13 Prof. Liu, UC Berkeley Summary of Biasing Techniques EE105 Fall 2007 Lecture 7, Slide 14 Prof. Liu, UC Berkeley PNP BJT Biasing Techniques • The same principles that apply to NPN BJT biasing also apply to PNP BJT biasing, with only voltage and current polarity modifications. EE105 Fall 2007 Lecture 7, Slide 15 Prof. Liu, UC Berkeley Possible BJT Amplifier Topologies • There are 3 possible ways to apply an input to an amplifier and 3 possible ways to sense its output. • In practice, only 3 out of the possible 6 input/output combinations are useful. EE105 Fall 2007 Lecture 7, Slide 16 Prof. Liu, UC Berkeley Common-Emitter (CE) Topology EE105 Fall 2007 Lecture 7, Slide 17 Prof. Liu, UC Berkeley Small Signal of CE Amplifier vout Av vin EE105 Fall 2007 Lecture 7, Slide 18 Prof. Liu, UC Berkeley Limitation on CE Voltage Gain • Since gm = IC/VT, the CE voltage gain can be written as a function of VRC , where VRC = VCC - VCE. • VCE should be larger than VBE for the BJT to be operating in active mode. I C RC VRC Av VT VT EE105 Fall 2007 Lecture 7, Slide 19 Prof. Liu, UC Berkeley Voltage-Gain / Headroom Tradeoff EE105 Fall 2007 Lecture 7, Slide 20 Prof. Liu, UC Berkeley I/O Impedances of CE Stage • When measuring output impedance, the input port has to be grounded so that vin = 0. vX Rout RC iX vX Rin r iX EE105 Fall 2007 Lecture 7, Slide 21 Prof. Liu, UC Berkeley CE Stage Design Trade-offs EE105 Fall 2007 Lecture 7, Slide 22 Prof. Liu, UC Berkeley Inclusion of the Early Effect • The Early effect results in reduced voltage gain of the CE amplifier. Av g m ( RC || rO ) Rout RC || rO EE105 Fall 2007 Lecture 7, Slide 23 Prof. Liu, UC Berkeley Intrinsic Gain • As RC goes to infinity, the voltage gain approaches its maximum possible value, gm × rO, which is referred to as the intrinsic gain. • The intrinsic gain is independent of the bias current: Av g m rO VA Av VT EE105 Fall 2007 Lecture 7, Slide 24 Prof. Liu, UC Berkeley Current Gain, AI • The current gain is defined as the ratio of current delivered to the load to current flowing into the input. • For a CE stage, it is equal to . iout AI iin AI EE105 Fall 2007 CE Lecture 7, Slide 25 Prof. Liu, UC Berkeley