R₁ = 56kN, R₂ = 12.2k, Rc = 2k, R= = 0.4k, Rg = 300k, Vcc = 10V. (1) For each circuit (a) and (b), calculate IBQ, ICQ and VCEQ for ß = 50, 100 and 150. Put your results in a table.3.1 (2) Calculate the percentage of change in the values of IBQ, ICQ and VCEQ corresponding to the change in the value of B for each circuit. (For example, for circuit (a), for a change of the value of ẞ from 50 to 100, the current Ico increases by.....%). (3) Based on your calculations in part (2), which bias configuration provides more stability (less sensitive to variations in B.

?1=56?Ω, ?2=12.2?Ω, ??=2?Ω, ??=0.4?Ω, ??=300?Ω, ???=10?.
(1) For each circuit (a) and (b), calculate ???, ??? and ???? for ?=50,100 ??? 150. Put your results in a table.3.1
(2) Calculate the percentage of change in the values of ???, ??? and ???? corresponding to the change in the value of β for each circuit. (For example, for circuit (a), for a change of the value of β from 50 to 100, the current ???increases by …..%).
(3) Based on your calculations in part (2), which bias configuration provides more stability (less sensitive to variations in β.

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R₁ = 56kN, R₂ = 12.2k, Rc : = = 2kN, R₂ = 0.4kN, RB = 300kn, Vcc = 10V. (1) For each circuit (a) and (b), calculate IBQ, ICQ and VCEQ for ß = 50, 100 and 150. Put your results in a table.3.1 (2) Calculate the percentage of change in the values of IBQ, ICQ and VCEQ corresponding to the change in the value of ß for each circuit. (For example, for circuit (a), for a change of the value of ẞ from 50 to 100, the current Ico increases by .....%). (3) Based on your calculations in part (2), which bias configuration provides more stability (less sensitive to variations in B. Vs Cc www (a) Vcc RB iB Rc UBE www UCE Cc www www +1₁ R₁ R₂ Vcc www Ico RC VCEQ RE (b)