Dr. Nasim Zafar Electronics 1 - EEE 231 Fall Semester – 2012 COMSATS Institute of Information Technology Virtual campus Islamabad
Potential-Divider-Biasing Circuits: Examples and Exercises.. Lecture No: 19 Contents: Base-Biased (Fixed Bias) Transistor Circuits. Voltage-Divider-Bias transistor Circuits. Examples and Exercises. Nasim Zafar2
References: Microelectronic Circuits: Adel S. Sedra and Kenneth C. Smith. Integrated Electronics : Jacob Millman and Christos Halkias (McGraw-Hill). Introductory Electronic Devices and Circuits Robert T. Paynter Electronic Devices : Thomas L. Floyd ( Prentice Hall ). Nasim Zafar3
Basic Circuits of BJT: NPN Transistor Nasim Zafar4 I E = I C + I B
Transistor Output Characteristics: 5Nasim Zafar
Transistor Output Characteristics: Load Line – Biasing and Stability: Active region: – BJT acts as a signal amplifier. – B-E junction is forward biased and C-B junction is reverse biased. Graphical construction for determining the dc collector current I C and the collector-to-emitter voltage V CE. The requirement is to set the Q-point such that that it does not go into the saturation or cutoff regions when an a ac signal is applied. Maximum signal swing depends on the bias voltage. Nasim Zafar6
The DC Operating Point: Biasing and Stability Active region - Amplifier: BJT acts as a Signal Amplifier. 1. B-E Junction Forward Biased V BE ≈ 0.7 V for Si 2. B-C Junction Reverse Biased 3. KCL: I E = I C + I B C B E IBIB IEIE ICIC C B E IBIB IEIE ICIC 7Nasim Zafar
The DC Operating Point: Biasing and Stability Slope of the Load Line: V CC = V CE + V RC V CE = V CC - V RC V CE = V CC - I C R C 8Nasim Zafar
9 Current Equations in a BJT: NPN Transistor Collector Current Base Current Emitter Current 9Nasim Zafar
1. Fixed-Biased Transistor Circuits. Base-Biased (Fixed Bias) Transistor Circuit: Single Power Supply 10Nasim Zafar
11 Base-Biased (Fixed Bias) Transistor Circuit: Advantage: Circuit simplicity. Disadvantage: Q-point shifts with temp. Applications: Switching circuits only. Circuit Recognition: A single resistor R B between the base terminal and V CC. No emitter resistor. Nasim Zafar Circuit Characteristics - 1:
12 Base-Biased (Fixed Bias) Transistor Circuit: Circuit Characteristics - 2: Load line equations: Q-point equations: Nasim Zafar
13 Base-Biased (Fixed Bias) Transistor Circuit: Q-point equations: Nasim Zafar 1. Base–Emitter Loop: V CC = V BE + I B R B
14 Base-Biased (Fixed Bias) Transistor Circuit: = dc current gain = h FE Nasim Zafar 2. Collector–Emitter Loop: V CC = V CE + V RC V CE = V CC - I C R
15 Circuit 19.1; Example 19.1 Nasim Zafar
16 Example 19.2 Construct the DC Load line for circuit 19.1; shown in slide 12, and plot the Q-point from the values obtained in Example Determine whether the circuit is midpoint biased. Nasim Zafar The circuit is midpoint biased.
17 Example 19.3 (Q-point Shift.) The transistor of Circuit 19.1, has values of h FE = 100 when T = 25 °C and h FE = 150 when T = 100 °C. Determine the Q-point values of I C and V CE at both of these temperatures. Temp(°C)I B (mA)I C (mA)V CE (V) Nasim Zafar
3. 2. Voltage-Divider-Bias Circuits. 18Nasim Zafar
Voltage-Divider Bias Circuits: NPN Transistor. Voltage-divider biasing is the most common form of transistor biasing used. A thorough understanding of the dc analysis of this circuit is essential for an electronic technician. In the Circuit, R1 and R2 set up a voltage divider on the base. Notice the similarity to the emitter-biased circuit. Nasim Zafar19
20 Voltage-Divider Bias Characteristics-(1) Circuit Recognition: The voltage divider in the base circuit. Advantages: The circuit Q- point values are stable against changes in h FE. Disadvantages: Requires more components than most other biasing circuits. Applications: Used primarily to bias linear amplifier. Nasim Zafar
21 Voltage-Divider Bias Characteristics-(2) The Thevenin voltage: Nasim Zafar
22 Voltage-Divider Bias Characteristics-(3) Load line equations: Q-point equations (assume that h FE R E > 10R 2 ): Nasim Zafar
23 Circuit 19.2; Example 19.4 (a). Determine the values of I CQ and V CEQ for the circuit 19.2 shown in Fig below: Because I I E (or h FE >> 1), Nasim Zafar
24 Circuit 19.2; Example 19.4 (b). Verify that I 2 > 10 I B. Nasim Zafar
25 Example 19.5 A voltage-divider bias circuit has the following values: R 1 = 1.5 kW, R 2 = 680 W, R C = 260 W, R E = 240 W and V CC = 10 V. Assuming the transistor is a 2N3904, determine the value of I B for the circuit. Nasim Zafar
26 Load Line for Voltage Divider Bias Circuit. Example 19.5 Nasim Zafar
27 Which value of h FE do we use? Transistor specification sheet may list any combination of the following h FE : max. h FE, min. h FE, or typ. h FE. Use typical value if there is one. Otherwise, use Nasim Zafar
28 Stability of Voltage Divider Bias Circuit: The Q-point of voltage divider bias circuit is less dependent on h FE than that of the base bias (fixed bias). For example, if I E is exactly 10 mA, the range of h FE is 100 to 300. Then I CQ hardly changes over the entire range of h FE. Nasim Zafar
Voltage-Divider Bias Circuit: Circuit-19.3; Problem 19.6 (a). Find the operating point Q for this circuit. The use of Thevenin equivalent circuit for the base makes the circuit simpler. Nasim Zafar29
Determination of V BB – The Thevenin Voltage V CC = I.(R 1 + R 2 ) -- Eq. (1) V Thev = I.R 2 Eq. (2) -- Eq. (3) Nasim Zafar30
Circuit-19.3; Problem 19.6 (a) Determination of V BB From Eq (3) V Thev = 2 Volts Nasim Zafar31
Circuit-19.3; Problem 19.6 (b). Determination of V RE Input Loop with R E V BB = V BE + V RE V RE = V BB – V BE V RE = 2V - 0.7V V RE = 1.3V Nasim Zafar32
Circuit-19.3; Problem 19.6 (c). Determination of I E V RE = I E R E Nasim Zafar33
Circuit-19.3; Problem 19.6 (d). Determination of V RC Since I E ≈ I C I E = 1.3mA Therefore, I C = 1.3mA V RC = I C R C = (1.3mA)(4x10 3 Ω) V RC = 5.2V Nasim Zafar34
Circuit-19.3; Problem 19.6 (e). Determination of V CE Output Loop V CC =V RC +V CE +V RE V CE = V CC -V RC -V RE V CE = 12V - 5.2V - 1.3V V CE = 5.5V Nasim Zafar35
Results of Problem 19.6 I E = I C = 1.3mA V RC = 5.2V V CE = 5.5V V RE = 1.3V V BB = 2V β dc was never used in a calculation. Hence, voltage-divider biased circuits are immune to changes in β dc. A single voltage source supplies both voltages, V CC and V BB Nasim Zafar36
Review of equations: In Review V RE = V BB – V BE I E ≈ I C Nasim Zafar37
Summary: Voltage-divider biased circuits are immune to changes in β dc. A single voltage source supplies both voltages, V CC and V BB The circuit Q-point values are stable against changes in h FE. Use of the Thevenin equivalent circuit for the base makes the circuit simpler. Make the current in the voltage divider about 10 times IB, to simplify the analysis. For design, solve for the resistor values (IC and VC specified). Nasim Zafar38
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Circuit 19.4; Problem 19.7 (a). Given: V B = 3V and I = 0.2mA. IBIB I (a) RB1 and RB2 form a voltage divider. Assume I >> IB I = V CC /(R B1 + R B2 ) 0.2mA = 9 /(R B1 + R B2 ) 40 Nasim Zafar
Circuit 19.4; Problem 19.7 (b). Given: V B = 3V and I = 0.2mA. R B1 = 30K , and R B2 = 15K . IBIB I V B = V CC [R B2 /(R B1 + R B2 )] 3 = 9 [R B2 /(R B1 + R B2 )], Solve for R B1 and R B2. 41 Nasim Zafar (b) Determination of the Thevenin voltage:
Prob (c). Find the operating point The use of Thevenin equivalent circuit for the base makes the circuit simpler. V BB = V B = 3V R BB = R B1 || R B2 = 30K 15K 10K 42Nasim Zafar
Problem 19.7 (d). Write B-E loop and C-E loop B-E loop C-E loop B-E Voltage Loop: V BB = V RBB + V BE + V R E V BB = I B R BB + V BE + I E R E I E =2.09 mA C-E Voltage Loop: V CC = I C R C + V CE + I E R E V CE =4.8 V This is how all DC circuits are analyzed and designed! 43Nasim Zafar
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Example 19.7 Stage 2 C-E loop I E2 I C2 V CC = I E2 R E2 + V EC2 +I C2 R C2 15 = 2.8(2) + V EC (2.7) solve for V EC2 V CE2 = 1.84V 45Nasim Zafar
Example 19.7 C-E loop neglect IB2 because it is IB2 << IC1 I E1 I C1 V CC = I C1 R C1 + V CE1 +I E1 R E1 15 = 1.3(5) + V CE1 +1.3(3) VCE1= 4.87V 46Nasim Zafar
Example 19.7 Stage 2 B-E loop I B2 I E2 V CC = I E2 R E2 + V EB +I B2 R BB2 + V BB2 15 = I E2 (2K) +.7 +I B2 (5K) (3) Use I B2 I E2 / solve for I E2 IE2 = 2.8mA 47Nasim Zafar
Example stage amplifier, 1st stage has an npn transistor; 2nd stage has an pnp transistor. I C = I B I C I E V BE = 0.7 (npn) = -0.7 (pnp) = 100 Find I C1, I C2, V CE1, V CE2 Use Thevenin circuits. 48Nasim Zafar
Example 19.7 R BB1 = R B1 ||R B2 = 33K V BB1 = V CC [R B2 /(R B1 +R B2 )] V BB1 = 15[50K/150K] = 5V Stage 1 B-E loop V BB1 = I B1 R BB1 + V BE +I E1 R E1 Use I B1 I E1 / 5 = I E1 33K / I E1 3K I E1 = 1.3mA I B1 I E1 49Nasim Zafar