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Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE) PDF Download

Q17: Two perfectly matched silicon transistor are connected as shown in the figure assuming the β of the transistors to be very high and the forward voltage drop in diodes to be 0.7 V, the value of current I is (2008)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) 0 mA
(b) 3.6 mA
(c) 4.3 mA
(d) 5.7 mA
Ans:
(b)
Sol: Since both transitor are perfectly matched,
So, VBE1 = VBE2
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Since \beta for both are same, therefore
Ib1 = Ib2 = Ib
Applying KVL to loop as shown,
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)By KCL,
IR = Ic+ 2Ib
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)≈ IR (Because β is very large)

Q18: The common emitter forward current gain of the transistor shown is βF = 100.  
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)The transistor is operating in (2007)
(a) Saturation region
(b) Cutoff region
(c) Reverse active region
(d) Forward active region
Ans: 
(d)
Sol: We assume BJT is in active region, applying KVL in base emitter circuit
10 − 0.7 = 1kΩ × Ic + 270 × Ib
= Ib(270 + 100k)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Ic(sat) > Ic(active)
∴ BJT is in active region.

Q19: Consider the circuit shown in figure. If the β of the transistor is 30 and ICBO is 20 mA and the input voltage is +5 V, the transistor would be operating in (2006)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) saturation region
(b) active region
(c) breakdown region
(d) cut-off region
Ans:
(b)
Sol: Assume BJT is in active Region and we neglect ICBO,
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)as Ic(sat) > Ic(active)
BJT is in active region.

Q20: Assume that the threshold voltage of the N-channel MOSFET shown in figure is + 0.75 V. The output characteristics of the MOSFET are also shown
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)The voltage gain of the amplifier is (2005)
(a) +5
(b) -7.5
(c) +10
(d) -10
Ans:
(d)
Sol: Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Since, r>> R
All current will pass through R
Vout = −gmVGSR
= −1 × 10−3 × 2 × 10−3 × 10 × 10−3
= −20mV
Volate gain Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)


Q21:  Assume that the threshold voltage of the N-channel MOSFET shown in figure is + 0.75 V. The output characteristics of the MOSFET are also shown
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE) The transconductance of the MOSFET is (2005)
(a) 0.75 ms
(b) 1 ms
(c) 2 ms
(d) 10 ms
Ans: 
(b)

Sol: Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)


Q22: The common emitter amplifier shown in the figure is biased using a 1 mA ideal current source. The approximate base current value is (2005)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) 0 μA
(b) 10 μA
(c) 100 μA
(d) 1000 μA
Ans: 
(b)

Sol: β = Ic/Ib
I= Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)


Q23: Assume that the N-channel MOSFET shown in the figure is ideal, and that its threshold voltage is +1.0 V. The voltage Vab between nodes a and b is: (2005)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE) (a) 5V
(b) 2V
(c) 1V
(d) 0V
Ans: 
(d)

Sol: MOSFET is N_channel. Gate through souce is so connected that MOSFET will be in enhance mode and so conductivity of the channel will be increased very much and effectively 'β' terminal act as short circuited, So,  Vab = 0V.

Q24: The value of R for which the PMOS transistor in figure will be biased in linear region is (2004)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) 220 Ω
(b) 470 Ω
(c) 680 Ω
(d) 1200 Ω
Ans:
(d)
Sol: Here
VS = +4V
VG = 0V
VT = −1V
Therefore, VSG = 4V
VSD = V− VD
= 4 − IaR
Now for linear region of operation VSD < (VSG − VT)
⇒ 4 − IaR < (4 − 1)
⇒ Ia(R) > 1
⇒ 10−3 × R > 1
R > 1000Ω

Q25: The transconductance gm of the transistor shown in figure is 10 mS. The value of the input resistance RIN is (2004)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) 10.0 kΩ
(b) 8.3 kΩ
(c) 5.0 kΩ
(d) 2.5 kΩ
Ans:
(d)
Sol: Input Resistance= Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)

But overall input resistance seen from source is
RIN = 10 ∥ 10 ∥ 5 = 2.5kΩ


Q26: Two perfectly matched silicon transistor are connected as shown in figure. The value of the current I is (2004)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) 0 mA
(b) 2.3 mA
(c) 4.3 mA
(d) 7.3 mA
Ans:
(c)
Sol: Both transistor are perfectly matched, hence
VBE2 = VBE1  
therefore, Ic1/Ic2 = exp[(VBE1 − VBE2)/VT] = 1
Also 'β' is same.
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)Writing KCL at node B,
Ic + 2Ib − IR = 0
Ic = βIb
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)≈ IR (Because β is very large)
Hence, Ic1 = Ic2 = IR = 4.3mA  

Q27: For the n-channel enhancement MOSFET shown in figure, the threshold voltage Vth = 2 V. The drain current ID of the MOSFET is 4 mA when the drain resistance RD is 1 kΩ. If the value of RD is increased to 4 kΩ, drain current ID will become (2003)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) 2.8mA
(b) 2.0mA
(c) 1.4mA
(d) 1.0mA
Ans: 
(c)
Sol: ID = K(VGS − Vth)2
4 = K(6 − 2)2
∴ K = (1/4)mA/V2
VGS = 10−4×1 = 6V
when RD is increased to 4kΩ
VGS = 10 − 4ID
I= 1/4(10 − 4I− 2)2
4I= 16I2D + 64 − 64ID
16I2D − 68ID + 64 = 0
ID = 2.84 mA, 1.4 mA
For MOSFET to be on, VGS must be greater than Vth and this is possible only if
ID = 1.4mA
If I= 2.84 mA
then VGS become -ve and less than Vth so transistor will be off for this value which is not possible since VDG = 0 ≥ − Vth.

Q28: In the circuit of figure, assume that the transistor has hFE = 99 and VBE = 0.7 V. The value of collector current IC of the transistor is approximately (2003)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) [3.3/3.3] mA
(b) [3.3/(3.3 +.33)] mA
(c) [3.3/33] mA
(d) [3.3/(33 + 3.3)] mA
Ans:
(b)
Sol: Using KVL in Base-emitter Loop
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)4 − 33 × Ib − 0.7 − 3.3 × 100Ib = 0(I= βIb)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)
Q29: The variation of drain current with gate-to-source voltage (ID - VGS characteristic) of a MOSFET is shown in figure. The MOSFET is (2003)
Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)(a) an n-channel depletion mode device
(b) an n-channel enhancement mode device
(c) an p-channel depletion mode device
(d) an p-channel enhancement mode device
Ans:
(c)
Sol: This is the characteristics of a p-channel depletion mode device.

Q30: An n-channel JFET, having a pinch-off voltage (Vp) of -5 V, shows a transconductance (gm) of 1 mA/V when the applied gate-to-source voltage (VGS) is -3V. Its maximum transconductance (in mA/V) is (2001)
(a) 1.5
(b) 2
(c) 2.5
(d) 3
Ans:
(c)
Sol: Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE)
The document Previous Year Questions- BJT, FET and their Biasing Circuits - 2 | Analog and Digital Electronics - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Analog and Digital Electronics.
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