Communication miscellaneous Easy Questions and Answers

Communication miscellaneous

Assuming other parameters unchanged if the modulating frequency is halved in a modulating systems, the modulation index is doubled. The modulation system is—

1. A M
1. FM
1. Phase modulation
1. Angle modulation

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Since modulation index is given by
β = K_fA_m
ω_m

given,
ω'_m = ω_m
2

Now,
β' = K_fA_m = 2β
ω_m/2

Hence alternative (B) is the correct choice.
Since here,
β ∝ 1
ω_m

Correct Option: B

Since modulation index is given by
β = K_fA_m
ω_m

given,
ω'_m = ω_m
2

Now,
β' = K_fA_m = 2β
ω_m/2

Hence alternative (B) is the correct choice.
Since here,
β ∝ 1
ω_m

In a single-tone FM discriminator (S₀/N₀) is—

1. proportional to deviation
1. proportional to cube of deviation
1. inversely proportional to deviation
1. proportional to square of deviation

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SNR in single tone FM is given by
δ₀ = 3 β²
N₀ 2

δ₀ = 3 Δf ²
N₀ 2 f_m

or
δ₀ ∝ Δf²
N₀

i.e. square of frequency deviation

Correct Option: D

SNR in single tone FM is given by
δ₀ = 3 β²
N₀ 2

δ₀ = 3 Δf ²
N₀ 2 f_m

or
δ₀ ∝ Δf²
N₀

i.e. square of frequency deviation

A narrowband FM does not have the following feature—

1. it has two sidebands
1. both sidebands are equal in amplitude
1. both sidebands have same phase difference with respect to carrier
1. it does not show amplitude variations

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In narrow band FM the lower sideband is negative, i.e. 180° out of phase as compared to the carrier. This makes the amplitude of FM approximately constant. Hence alternative (C) is most suitable choice.

Correct Option: C

In narrow band FM the lower sideband is negative, i.e. 180° out of phase as compared to the carrier. This makes the amplitude of FM approximately constant. Hence alternative (C) is most suitable choice.

A non-linear device with a transfer characteristic given by i = (0 + 2V_i + 0·2V_i²) mA is supplied with a carrier of 1V amplitude and a sinusoidal signal of 0.5V amplitude in series. If at the output the frequency component of AM signal is considered, the depth of modulation is—

1. 18%
1. 10%
1. 20%
1. 33.33%

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Given transfer characteristic
i = (10 + 2V_i + 0·2 V_i²) mA …(A)
Since, according to question both carrier and sinusoidal signals are in series. Let assume V_i is represented as
V_i = A_m cos ω_mt + A_c cos ω_ct
or
V_i = 0·5 cos ω_mt + cos ω_ct (˙.˙ A_m = 0·5V, A_c = 1V)
Now, on putting the value of V_i in equation (A) we get amplitude modulated AM signal i.e.,
i = 10 + 2 (cos ω_ct + 0·5 cos ω_mt) + 0·2 (cos ω_ct + 0·5 cos ω_mt)²
or
i = 2 cos ω_c t + 0·2 cos ω_ct + cos ω_mt
(˙.˙ At the output only lower frequency terms are considered and neglecting the higher frequency terms)
i = 2 1 + 0.2 cos ω_mt cos ω_ct
2
...(B)
which is equal to standard AM equation.
i = A_c (1 + μ cos ω_mt) cos ω_ct …(C)
So, on comparing equation (B) and (C) we get
μ = 0.2 = 0.1
2

and% modulation index = 0.1 x 100 = 10%.
Hence alternative (B) is the correct choice.

Correct Option: B

Given transfer characteristic
i = (10 + 2V_i + 0·2 V_i²) mA …(A)
Since, according to question both carrier and sinusoidal signals are in series. Let assume V_i is represented as
V_i = A_m cos ω_mt + A_c cos ω_ct
or
V_i = 0·5 cos ω_mt + cos ω_ct (˙.˙ A_m = 0·5V, A_c = 1V)
Now, on putting the value of V_i in equation (A) we get amplitude modulated AM signal i.e.,
i = 10 + 2 (cos ω_ct + 0·5 cos ω_mt) + 0·2 (cos ω_ct + 0·5 cos ω_mt)²
or
i = 2 cos ω_c t + 0·2 cos ω_ct + cos ω_mt
(˙.˙ At the output only lower frequency terms are considered and neglecting the higher frequency terms)
i = 2 1 + 0.2 cos ω_mt cos ω_ct
2
...(B)
which is equal to standard AM equation.
i = A_c (1 + μ cos ω_mt) cos ω_ct …(C)
So, on comparing equation (B) and (C) we get
μ = 0.2 = 0.1
2

and% modulation index = 0.1 x 100 = 10%.
Hence alternative (B) is the correct choice.

A diode detector has a load of 1kΩ shunted by a 10000 pF capacitor. The diode has a forward resistance of 1Ω. The maximum permissible depth of modulation, so as to avoid diagonal clipping, with modulating signal frequency of 10kHz will be—

1. 0.847
1. 0.628
1. 0.734
1. None of these

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We know that
RC ≤ 1 √ 1 − μ²
ω_m μ²

given that R = 1 kΩ = 1000Ω
C = 10000 pf = 10^–8 f
ω_m = 2π f_m = 2π × 10 × 10³ radian/sec
μ =? (neglecting diode forward resistance i.e.1Ω)
1000 × 10⁻⁸ ≤ 1 √ 1 − μ²
2π × 10 ×10³ μ²

or
0.628 ≤ √ 1 − μ²
μ²

or
0.394 ≤ 1 − μ²
μ²

or
0.394 μ² ≤ 1 − μ²
or
1.394 μ² ≤ 1
or
μ² ≤ 1
1.394

or
μ ≤ 0.8469
or
μ_max ≤ 0.847
Hence alternative (A) is the correct choice.

Correct Option: A

We know that
RC ≤ 1 √ 1 − μ²
ω_m μ²

given that R = 1 kΩ = 1000Ω
C = 10000 pf = 10^–8 f
ω_m = 2π f_m = 2π × 10 × 10³ radian/sec
μ =? (neglecting diode forward resistance i.e.1Ω)
1000 × 10⁻⁸ ≤ 1 √ 1 − μ²
2π × 10 ×10³ μ²

or
0.628 ≤ √ 1 − μ²
μ²

or
0.394 ≤ 1 − μ²
μ²

or
0.394 μ² ≤ 1 − μ²
or
1.394 μ² ≤ 1
or
μ² ≤ 1
1.394

or
μ ≤ 0.8469
or
μ_max ≤ 0.847
Hence alternative (A) is the correct choice.

β =	K_fA_m
	ω_m

ω'_m =	ω_m
	2

β' =	K_fA_m	= 2β
	ω_m/2

β ∝	1
	ω_m

Communication miscellaneous

Communication miscellaneous

Communication

Correct Option: B

Correct Option: D

Correct Option: C

Correct Option: B

Correct Option: A