22 + Mcqs in General Considerations Design Digital Filters Page 1 McqOptions

1.	The frequency ωP is called as ______________
A.	Pass band ripple
B.	Stop band ripple
C.	Pass band edge ripple
D.	Stop band edge ripple
Answer» D. Stop band edge ripple

Discussion

2.	The magnitude \|H(ω)\| cannot be constant in any finite range of frequencies and the transition from pass-band to stop-band cannot be infinitely sharp.
A.	True
B.	False
Answer» B. False

Discussion

3.	The HI(ω) is uniquely determined from HR(ω) through the integral relationship. This integral is called as Continuous Hilbert transform.
A.	True
B.	False
Answer» C.

Discussion

4.	What is the Fourier transform of the unit step function U(ω)?
A.	πδ(ω)-0.5-j0.5cot(ω/2)
B.	πδ(ω)-0.5+j0.5cot(ω/2)
C.	πδ(ω)+0.5+j0.5cot(ω/2)
D.	πδ(ω)+0.5-j0.5cot(ω/2)
Answer» E.

Discussion

5.	HR(ω) and HI(ω) are interdependent and cannot be specified independently when the system is causal.
A.	True
B.	False
Answer» B. False

Discussion

6.	If h(n) is absolutely summable, i.e., BIBO stable, then the equation for the frequency response H(ω) is given as?
A.	HI(ω)-j HR(ω)
B.	HR(ω)-j HI(ω)
C.	HR(ω)+j HI(ω)
D.	HI(ω)+j HR(ω)
Answer» D. HI(ω)+j HR(ω)

Discussion

7.	If h(n) is causal and h(n)=he(n)+ho(n),then what is the expression for h(n) in terms of only ho(n)?
A.	h(n)=2ho(n)u(n)+h(0)δ(n), n ≥ 0
B.	h(n)=2ho(n)u(n)+h(0)δ(n), n ≥ 1
C.	h(n)=2ho(n)u(n)-h(0)δ(n), n ≥ 1
D.	h(n)=2ho(n)u(n)-h(0)δ(n), n ≥ 0
Answer» C. h(n)=2ho(n)u(n)-h(0)δ(n), n ≥ 1

Discussion

8.	If h(n) is causal and h(n)=he(n)+ho(n),then what is the expression for h(n) in terms of only he(n)?
A.	h(n)=2he(n)u(n)+he(0)δ(n), n ≥ 0
B.	h(n)=2he(n)u(n)+he(0)δ(n), n ≥ 1
C.	h(n)=2he(n)u(n)-he(0)δ(n), n ≥ 1
D.	h(n)=2he(n)u(n)-he(0)δ(n), n ≥ 0
Answer» E.

Discussion

9.	The magnitude function \|H(ω)\| can be zero at some frequencies, but it cannot be zero over any finite band of frequencies.
A.	True
B.	False
Answer» B. False

Discussion

10.	If \|H(ω)\| is square integrable and if the integral $\int_{-\pi}^\pi \|ln⁡\|H(ω)\|\|dω$ is finite, then the filter with the frequency response H(ω)=\|H(ω)\|ejθ(ω) is?
A.	Anti-causal
B.	Constant
C.	Causal
D.	None of the mentioned
Answer» D. None of the mentioned

Discussion

11.	If h(n) has finite energy and h(n)=0 for n
A.	$\int_{-π}^π\|ln⁡ \|H(ω)\|\|dω \gt -\infty$
B.	$\int_{-π}^π\|ln⁡ \|H(ω)\|\|dω \lt \infty$
C.	$\int_{-π}^π\|ln⁡\|H(ω)\|\|dω = \infty$
D.	None of the mentioned
Answer» C. $\int_{-π}^π\|ln⁡\|H(ω)\|\|dω = \infty$

Discussion

12.	The following diagram represents the unit sample response of which of the following filters?
A.	Ideal high pass filter
B.	Ideal low pass filter
C.	Ideal high pass filter at ω=π/4
D.	Ideal low pass filter at ω=π/4
Answer» E.

Discussion

13.	HR(‚ÂÀ√¨‚ÀÖ¬¢)_AND_HI(‚ÂÀ√¨‚ÀÖ¬¢)_ARE_INTERDEPENDENT_AND_CANNOT_BE_SPECIFIED_INDEPENDENTLY_WHEN_THE_SYSTEM_IS_CAUSAL.?$#
A.	True
B.	False
Answer» B. False

Discussion

14.	The HI(‚âà√¨‚àö¬¢) is uniquely determined from HR(‚âà√¨‚àö¬¢) through the integral relationship. This integral is called as Continuous Hilbert transform.$#
A.	True
B.	False
Answer» C.

Discussion

15.	What_is_the_Fourier_transform_of_the_unit_step_function_U(‚âà√¨‚àö¬¢)?$#
A.	‚âà√¨‚àö√ë‚âà√≠¬¨‚Ä¢(‚âà√¨‚àö¬¢)-0.5-j0.5cot(‚âà√¨‚àö¬¢/2)
B.	‚âà√¨‚àö√ë‚âà√≠¬¨‚Ä¢(‚âà√¨‚àö¬¢)-0.5+j0.5cot(‚âà√¨‚àö¬¢/2)
C.	‚âà√¨‚àö√ë‚âà√≠¬¨‚Ä¢(‚âà√¨‚àö¬¢)+0.5+j0.5cot(‚âà√¨‚àö¬¢/2)
D.	‚âà√¨‚àö√ë‚âà√≠¬¨‚Ä¢(‚âà√¨‚àö¬¢)+0.5-j0.5cot(‚âà√¨‚àö¬¢/2)
Answer» E.

Discussion

16.	Which of the following represents the bandwidth of the filter?
A.	‚âà√¨‚àö¬¢<sub>P</sub>+ ‚âà√¨‚àö¬¢<sub>S</sub>
B.	-‚âà√¨‚àö¬¢<sub>P</sub>+ ‚âà√¨‚àö¬¢<sub>S</sub>
C.	‚âà√¨‚àö¬¢<sub>P</sub>-‚âà√¨‚àö¬¢<sub>S</sub>
D.	None of the mentioned
Answer» C. ‚âà√¨‚àö¬¢<sub>P</sub>-‚âà√¨‚àö¬¢<sub>S</sub>

Discussion

17.	The frequency ‚âà√¨‚àö¬¢P is called as:$
A.	Pass band ripple
B.	Stop band ripple
C.	Pass band edge ripple
D.	Stop band edge ripple
Answer» D. Stop band edge ripple

Discussion

18.	The_magnitude_\|H(‚âà√¨‚àö¬¢)\|_cannot_be_constant_in_any_finite_range_of_frequencies_and_the_transition_from_pass-band_to_stop-band_cannot_be_infinitely_sharp.$
A.	True
B.	False
Answer» B. False

Discussion

19.	If h(n) is absolutely summable, i.e., BIBO stable, then the equation for the frequency response H(‚âà√¨‚àö¬¢) is given as?#
A.	H<sub>I</sub>(‚âà√¨‚àö¬¢)-j H<sub>R</sub>(‚âà√¨‚àö¬¢)
B.	H<sub>R</sub>(‚âà√¨‚àö¬¢)-j H<sub>I</sub>(‚âà√¨‚àö¬¢)
C.	H<sub>R</sub>(‚âà√¨‚àö¬¢)+j H<sub>I</sub>(‚âà√¨‚àö¬¢)
D.	H<sub>I</sub>(‚âà√¨‚àö¬¢)+j H<sub>R</sub>(‚âà√¨‚àö¬¢)
Answer» D. H<sub>I</sub>(‚âà√¨‚àö¬¢)+j H<sub>R</sub>(‚âà√¨‚àö¬¢)

Discussion

20.	If h(n) is causal and h(n)=he(n)+ho(n),then what is the expression for h(n) in terms of only he(n)?
A.	h(n)=2h<sub>e</sub>(n)u(n)+h<sub>e</sub>(0)‚âà√≠¬¨‚Ä¢(n) ,n ‚Äö√Ñ√∂‚àö¬¢‚Äö√Ñ¬¢ 0
B.	h(n)=2h<sub>e</sub>(n)u(n)+h<sub>e</sub>(0)‚âà√≠¬¨‚Ä¢(n) ,n ‚Äö√Ñ√∂‚àö¬¢‚Äö√Ñ¬¢ 1
C.	h(n)=2h<sub>e</sub>(n)u(n)-h<sub>e</sub>(0)‚âà√≠¬¨‚Ä¢(n) ,n ‚Äö√Ñ√∂‚àö¬¢‚Äö√Ñ¬¢ 1
D.	h(n)=2h<sub>e</sub>(n)u(n)-h<sub>e</sub>(0)‚âà√≠¬¨‚Ä¢(n) ,n ‚Äö√Ñ√∂‚àö¬¢‚Äö√Ñ¬¢ 0
Answer» E.

Discussion

21.	The magnitude function \|H(‚âà√¨‚àö¬¢)\| can be zero at some frequencies, but it cannot be zero over any finite band of frequencies.$
A.	True
B.	False
Answer» B. False

Discussion

22.	The ideal low pass filter cannot be realized in practice.
A.	True
B.	False
Answer» B. False

Discussion

Explore topic-wise MCQs in Digital Signal Processing.

The frequency ωP is called as ______________

The magnitude |H(ω)| cannot be constant in any finite range of frequencies and the transition from pass-band to stop-band cannot be infinitely sharp.

The HI(ω) is uniquely determined from HR(ω) through the integral relationship. This integral is called as Continuous Hilbert transform.

What is the Fourier transform of the unit step function U(ω)?

HR(ω) and HI(ω) are interdependent and cannot be specified independently when the system is causal.

If h(n) is absolutely summable, i.e., BIBO stable, then the equation for the frequency response H(ω) is given as?

If h(n) is causal and h(n)=he(n)+ho(n),then what is the expression for h(n) in terms of only ho(n)?

If h(n) is causal and h(n)=he(n)+ho(n),then what is the expression for h(n) in terms of only he(n)?

The magnitude function |H(ω)| can be zero at some frequencies, but it cannot be zero over any finite band of frequencies.

If |H(ω)| is square integrable and if the integral \(\int_{-\pi}^\pi |ln⁡|H(ω)||dω\) is finite, then the filter with the frequency response H(ω)=|H(ω)|ejθ(ω) is?

If h(n) has finite energy and h(n)=0 for n

The following diagram represents the unit sample response of which of the following filters?

HR(‚ÂÀ√¨‚ÀÖ¬¢)_AND_HI(‚ÂÀ√¨‚ÀÖ¬¢)_ARE_INTERDEPENDENT_AND_CANNOT_BE_SPECIFIED_INDEPENDENTLY_WHEN_THE_SYSTEM_IS_CAUSAL.?$#

The HI(‚âà√¨‚àö¬¢) is uniquely determined from HR(‚âà√¨‚àö¬¢) through the integral relationship. This integral is called as Continuous Hilbert transform.$#

What_is_the_Fourier_transform_of_the_unit_step_function_U(‚âà√¨‚àö¬¢)?$#

Which of the following represents the bandwidth of the filter?

The frequency ‚âà√¨‚àö¬¢P is called as:$

The_magnitude_|H(‚âà√¨‚àö¬¢)|_cannot_be_constant_in_any_finite_range_of_frequencies_and_the_transition_from_pass-band_to_stop-band_cannot_be_infinitely_sharp.$

If h(n) is absolutely summable, i.e., BIBO stable, then the equation for the frequency response H(‚âà√¨‚àö¬¢) is given as?#

If h(n) is causal and h(n)=he(n)+ho(n),then what is the expression for h(n) in terms of only he(n)?

The magnitude function |H(‚âà√¨‚àö¬¢)| can be zero at some frequencies, but it cannot be zero over any finite band of frequencies.$

The ideal low pass filter cannot be realized in practice.

11.	If h(n) has finite energy and h(n)=0 for n
A.	\(\int_{-π}^π\|ln⁡ \|H(ω)\|\|dω \gt -\infty\)
B.	\(\int_{-π}^π\|ln⁡ \|H(ω)\|\|dω \lt \infty\)
C.	\(\int_{-π}^π\|ln⁡\|H(ω)\|\|dω = \infty\)
D.	None of the mentioned
Answer» C. \(\int_{-π}^π\|ln⁡\|H(ω)\|\|dω = \infty\)