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46-50) Use the BJT network below: (Use Exact Analysis) Vcc = 24V VBE1 = VBE2 = 0.7V B, = 80 B2 = 100 Voo R1 2kn R2 = 480kN R3 = 500 %3D %3D R4 = 12kN R5 1kn %3D Ri 46) Determine the value of the current “I". a. 10.087 mA Ra b. 1.870 mA c. 8.710 mA d. 7.108 mA 47) Determine the emitter voltage of transistor 1 (Vg1). a. 5. 468 V b. 4.568 V c. 8.654 V d. 6.845 V 48) Determine the collector voltage of transistor 2 (Vc2). a. 4.642 V b. 9.426 V c. 6. 924 V d. 2.429 V 49) Determine the base-collector voltage of transistor 1 (VBC1). a. -0.523 V b. -0.278 V c. -0.756 V d. -0.072 V 50) Determine the power dissipation of transistor 2 (P2) a. 16.309 mW b. 13.069 mW c. 10.369 mW d. 19.306 mW

46-50) Use the BJT network below: (Use Exact Analysis) Vcc = 24V VBE1 = VBE2 = 0.7V B, = 80 B2 = 100 Voo R1 2kn R2 = 480kN R3 = 500 %3D %3D R4 = 12kN R5 1kn %3D Ri 46) Determine the value of the current “I". a. 10.087 mA Ra b. 1.870 mA c. 8.710 mA d. 7.108 mA 47) Determine the emitter voltage of transistor 1 (Vg1). a. 5. 468 V b. 4.568 V c. 8.654 V d. 6.845 V 48) Determine the collector voltage of transistor 2 (Vc2). a. 4.642 V b. 9.426 V c. 6. 924 V d. 2.429 V 49) Determine the base-collector voltage of transistor 1 (VBC1). a. -0.523 V b. -0.278 V c. -0.756 V d. -0.072 V 50) Determine the power dissipation of transistor 2 (P2) a. 16.309 mW b. 13.069 mW c. 10.369 mW d. 19.306 mW

Introductory Circuit Analysis (13th Edition)
Introductory Circuit Analysis (13th Edition)
13th Edition
ISBN:9780133923605
Author:Robert L. Boylestad
Publisher:Robert L. Boylestad
Chapter1: Introduction
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answer number 50.show your solution pls. choose the correct answer 

46-50) Use the BJT network below: (Use Exact Analysis) Vcc = 24V VBE1 = VBE2 = 0.7V B1 = 80 ß2 = 100 R = 2kn R2 = 480kN R3 = 500 R4 = 12kN R5 = 1kN Voo %3D %3D %3D 46) Determine the value of the current "I". a. 10.087 mA Ri b. 1.870 mA c. 8.710 mA d. 7.108 mA 47) Determine the emitter voltage of transistor 1 (VẸ1). a. 5. 468 V b. 4.568 V c. 8.654 V d. 6.845 V 48) Determine the collector voltage of transistor 2 (Vc2). a. 4.642 V b. 9.426 V c. 6. 924 V d. 2.429 V 49) Determine the base-collector voltage of transistor 1 (VBC1). a. -0.523 V b. -0.278 V c. -0.756 V d. -0.072 V 50) Determine the power dissipation of transistor 2 (P2) a. 16.309 mW b. 13. 069 mW c. 10.369 mW d. 19.306 mW
Transcribed Image Text:46-50) Use the BJT network below: (Use Exact Analysis) Vcc = 24V VBE1 = VBE2 = 0.7V B1 = 80 ß2 = 100 R = 2kn R2 = 480kN R3 = 500 R4 = 12kN R5 = 1kN Voo %3D %3D %3D 46) Determine the value of the current "I". a. 10.087 mA Ri b. 1.870 mA c. 8.710 mA d. 7.108 mA 47) Determine the emitter voltage of transistor 1 (VẸ1). a. 5. 468 V b. 4.568 V c. 8.654 V d. 6.845 V 48) Determine the collector voltage of transistor 2 (Vc2). a. 4.642 V b. 9.426 V c. 6. 924 V d. 2.429 V 49) Determine the base-collector voltage of transistor 1 (VBC1). a. -0.523 V b. -0.278 V c. -0.756 V d. -0.072 V 50) Determine the power dissipation of transistor 2 (P2) a. 16.309 mW b. 13. 069 mW c. 10.369 mW d. 19.306 mW
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