Figure 2-4B.—Amplifiers showing reactive elements and reactance

2-10 Figure 2-4B.—Amplifiers showing reactive elements and reactance. The actual circuit components are: C1, C2, C3, R1, R2, R3, and Q1. C1 is used to couple the input signal. R1 develops the input signal. R2, the emitter resistor, is used for proper biasing and temperature stability. C2 is a decoupling capacitor for R2. R3 develops the output signal. C3 couples the output signal to the next stage. Q1 is the amplifying device. The phantom circuit elements representing the capacitance and inductance of the wiring are: L1, L2, C4, and C5. L1 represents the inductance of the input wiring. L2 represents the inductance of the output wiring. C4 represents the capacitance of the input wiring. C5 represents the capacitance of the output wiring. In view (A) the circuit is shown with a low-frequency input signal. Since the formulas for capacitive reactance and inductive reactance are: You should remember that if frequency is low, capacitive reactance will be high and inductive reactance will be low. This is shown by the position of the variable resistors that represent the reactances. Notice that X_L1 and X_L2 are low; therefore, they do not "drop" very much of the input and output signals. X_C4 and X_C5 are high; these reactances tend to "block" the input and output signals and keep them from going to the power supplies (V_BB and V_CC). Notice that the output signal is larger in amplitude than the input signal. Now look at view (B). The input signal is a high-frequency signal. Now X_C is low and X_L is high. X_L1 and X_L2 now drop part of the input and output signals. At the same time X_C4 and X_C5 tend to "short" or "pass" the input and output signals to signal ground. The net effect is that both the input and output signals are reduced. Notice that the output signal is smaller in amplitude than the input signal. Now you can see how the capacitance and inductance of the wiring affect an amplifier, causing the output of an amplifier to be less for high-frequency signals than for low-frequency signals.