Voltage Divider Bias

1. Voltage Divider Bias ENGI 242 ELEC 222

2. BJT Biasing 3 For the Voltage Divider Bias Configurations • Draw Equivalent Input circuit • DrawEquivalent Output circuit • Write necessary KVL and KCL Equations • Determine the Quiescent Operating Point • Graphical Solution using Load lines • Computational Analysis • Design and test design using a computer simulation ENGI 242/ELEC 222

3. Voltage-divider bias configuration ENGI 242/ELEC 222

4. Voltage Divider Input Circuit Approximate Analysis This method is valid only ifR2 .1  RE Under these conditions RE does not significantly load R2 and it may be ignored: IB << I1and I2 and I1 I2Therefore: • We may apply KVL to the input, which gives us: • -VB + VBE + IE RE = 0 • Solving for IE we get: ENGI 242/ELEC 222

5. Input Circuit Exact Analysis This method is always valid must be used when R2> .1  RE Perform Thevenin’s Theorem Open the base lead of the transistor, and the Voltage Divider bias circuit is: Calculate RTH We may apply KVL to the input, which gives us: -VTH + IB RTH + VBE + IE RE = 0 Since IE = ( + 1) IB ENGI 242/ELEC 222

6. Redrawing the input circuit for the network ENGI 242/ELEC 222

7. Determining VTH ENGI 242/ELEC 222

8. Determining RTH ENGI 242/ELEC 222

9. The Thévenin Equivalent Circuit Note that VE = VB – VBE and IE = ( + 1)IB ENGI 242/ELEC 222

10. Input Circuit Exact Analysis We may apply KVL to the input, which gives us: -VTH + IB RTH + VBE + IE RE = 0 Since IE = ( + 1) IB ENGI 242/ELEC 222

11. Collector-Emitter Loop ENGI 242/ELEC 222

12. Collector-Emitter (Output) Loop Applying Kirchoff’s voltage law: - VCC + IC RC + VCE + IE RE = 0 Assuming that IE IC and solving for VCE: Solve for VE: VE = IE RE Solve for VC: VC = VCC - IC RC or VC = VCE + IE RE Solve for VB: VB = VCC - IB RB or VB = VBE + IE RE ENGI 242/ELEC 222

13. Voltage Divider Bias Example 1 VCC = 22V R1 = 39k R2 = 3.9k RC = 10k RE = 1.5k  = 140 ENGI 242/ELEC 222

14. Voltage Divider Bias Example 2 VCC = 18V R1 = 39k R2 = 8.2k RC = 3.3k RE = 1k  = 120 ENGI 242/ELEC 222

15. Voltage Divider Bias Example 3 VCC = 16V R1 = 62k R2 = 9.1k RC = 3.9k RE = .68k  = 80 ENGI 242/ELEC 222

16. Design of CE Amplifier with Voltage Divider Bias • Select a value for VCC • Determine the value of  from spec sheet or family of curves • Select a value for ICQ • Let VCE = ½ VCC (typical operation, 0.4 VCC≤ VC≤ 0.6 VCC) • Let VE = 0.1 VCC(for good operation, 0.1 VCC≤ VE≤ 0.2 VCC) • Calculate RE and RC • Let R2≤ 0.1  RE (for this calculation, use low value for ) • Calculate R1 ENGI 242/ELEC 222

17. CE Amplifier Design • Design a Common Emitter Amplifier with Voltage Divider Bias for the following parameters: VCC = 24V IC = 5mA VE = .1VCC VC = .55VCC  = 135 ENGI 242/ELEC 222

18. ENGI 242/ELEC 222

19. CE Amplifier Design ENGI 242/ELEC 222

20. CE Amplifier Design Voltage Divider Bias ENGI 242/ELEC 222

21. Collector Feedback Bias ENGI 242 ELEC 222

22. BJT Biasing 4 For the Collector Feedback Bias Configuration: • Draw Equivalent Input circuit • DrawEquivalent Output circuit • Write necessary KVL and KCL Equations • Determine the Quiescent Operating Point • Graphical Solution using Loadlines • Computational Analysis • Design and test design using a computer simulation ENGI 242/ELEC 222

23. DC Bias with Collector (Voltage) Feedback Another way to improve the stability of a bias circuit is to add a feedback path from collector to base In this bias circuit the Q-point is only slightly dependent on the transistor  ENGI 242/ELEC 222

24. Base – Emitter Loop Solve for IB Applying Kirchoff’s voltage law: -VCC + ICRC + IBRB + VBE + IERE = 0 Note: IC = IE = IC + IB Since IE = ( + 1) IB then: -VCC + ( + 1)IB RC + IBRB + VBE ( + 1)IBRE = 0 Simplifying and solving for IB: ENGI 242/ELEC 222

25. Base – Emitter Loop Solve for IE Applying Kirchoff’s voltage law: -VCC + IERC + IBRB + VBE + IERE = 0 Since IE = ( + 1) IB then: Simplifying and solving for IE: ENGI 242/ELEC 222

26. Collector Emitter Loop Applying Kirchoff’s voltage law: IE RE + VCE + ICRC – VCC = 0 Since IC= IE and IE = ( + 1) IB: IE(RC + RE) + VCE – VCC =0 Solving for VCE: VCE = VCC – IE (RE + RC) ENGI 242/ELEC 222

27. Network Example ENGI 242/ELEC 222

28. Network Example ENGI 242/ELEC 222

29. Collector feedback with RE = 0 ENGI 242/ELEC 222

30. Design of CE Amplifier with Collector Feedback Bias • Select a value for VCC • Determine the value of  from spec sheet or family of curves • Select a value for IEQ • Let VCE = ½ VCC (typical operation, 0.4 VCC≤ VC≤ 0.6 VCC) • Let VE = 0.1 VCC(for good operation, 0.1 VCC≤ VE≤ 0.2 VCC) • Calculate RE, RC and RB ENGI 242/ELEC 222

31. Common Emitter Bias with Dual Supplies

32. Voltage Divider Bias with Dual Power Supply ENGI 242/ELEC 222

33. Voltage Divider Bias with Dual Power Supply Input Circuit Find VTH and RTH ENGI 242/ELEC 222

34. Voltage Divider Bias with Dual Power Supply Output Circuit ENGI 242/ELEC 222

35. Voltage Divider Bias with Dual Power Supply ENGI 242/ELEC 222

36. PSpice Simulation

37. PSpice Bias Point Simulation ENGI 242/ELEC 222

38. PSpice Simulation for DC Bias ENGI 242/ELEC 222

39. PSpice Simulation for DC Sweep ENGI 242/ELEC 222

40. PSpice Simulation for DC Sweep The response of VC demonstrates rises rapidly towards the Q Point and then increases gradually towards a maximum value The response of VCE demonstrates that it reaches a peak value near the Q point and then decreases ENGI 242/ELEC 222

41. PSpice Simulation for AC Sweep ENGI 242/ELEC 222

42. PSpice Simulation for AC Sweep ENGI 242/ELEC 222