Design of Linear Phase FIR Filters by Frequency Sampling Method MCQ [Free PDF] – Objective Question Answer for Design of Linear Phase FIR Filters by Frequency Sampling Method Quiz

1. In the frequency sampling method for FIR filter design, we specify the desired frequency response Hd(ω) at a set of equally spaced frequencies.

A. True
B. False

In the frequency sampling method, we specify the frequency response Hd(ω) at a set of equally spaced frequencies, namely ωk=$$\frac{2π}{M}(k+\alphA.$$

2. To reduce side lobes, in which region of the filter do the frequency specifications have to be optimized?

A. Stopband
B. Passband
C. Transition band
D. None of the mentioned

To reduce the side lobes, it is desirable to optimize the frequency specification in the transition band of the filter. This optimization can be accomplished numerically on a digital computer by means of linear programming techniques.

3. What is the frequency response of a system with input h(n) and window length of M?

A. $$\sum_{n=0}^{M-1} h(n)e^{jωn}$$

B. $$\sum_{n=0}^{M} h(n)e^{jωn}$$

C. $$\sum_{n=0}^M h(n)e^{-jωn}$$

D. $$\sum_{n=0}^{M-1} h(n)e^{-jωn}$$

The desired output of an FIR filter with an input h(n) and using a window of length M is given as

H(ω)=$$\sum_{n=0}^{M-1} h(n)e^{-jωn}$$

4. What is the relation between H(k+α) and h(n)?

A. H(k+α)=$$\sum_{n=0}^{M+1} h(n)e^{-j2π(k+α)n/M}$$; k=0,1,2…M+1

B. H(k+α)=$$\sum_{n=0}^{M-1} h(n)e^{-j2π(k+α)n/M}$$; k=0,1,2…M-1

C. H(k+α)=$$\sum_{n=0}^M h(n)e^{-j2π(k+α)n/M}$$; k=0,1,2…M

D. None of the mentioned

We know that

ωk=$$\frac{2π}{M}$$(k+α) and H(ω)=$$\sum_{n=0}^{M-1} h(n)e^{-jωn}$$

Thus from substituting the first in the second equation, we get

H(k+α)=$$\sum_{n=0}^{M-1} h(n)e^{-j2π(k+α)n/M}$$; k=0,1,2…M-1

5. Which of the following is the correct expression for h(n) in terms of H(k+α)?

A. $$\frac{1}{M} \sum_{k=0}^{M-1}H(k+α)e^{j2π(k+α)n/M}$$; n=0,1,2…M-1

B. $$\sum_{k=0}^{M-1}H(k+α)e^{j2π(k+α)n/M}$$; n=0,1,2…M-1

C. $$\frac{1}{M} \sum_{k=0}^{M+1}H(k+α)e^{j2π(k+α)n/M}$$; n=0,1,2…M+1

D. $$\sum_{k=0}^{M+1}H(k+α)e^{j2π(k+α)n/M}$$; n=0,1,2…M+1

We know that

H(k+α)=$$\sum_{n=0}^{M-1} h(n)e^{-j2π(k+α)n/M}$$; k=0,1,2…M-1

If we multiply the above equation on both sides by the exponential exp(j2πkm/M), m=0,1,2….M-1 and sum over k=0,1,….M-1, we get the equation

h(n)=$$\frac{1}{M} \sum_{k=0}^{M-1}H(k+α)e^{j2π(k+α)n/M}$$; n=0,1,2…M-1

6. Which of the following is equal to the value of H(k+α)?

A. H*(M-k+α)
B. H*(M+k+α)
C. H*(M+k-α)
D. H*(M-k-α)

Since {h(n)} is real, we can easily show that the frequency samples {H(k+α)} satisfy the symmetry condition
H(k+α)= H*(M-k-α).

7. The linear equations for determining {h(n)} from {H(k+α)} are not simplified.

A. True
B. False

The symmetry condition, along with the symmetry conditions for {h(n)}, can be used to reduce the frequency specifications from M points to (M+1)/2 points for M odd and M/2 for M even. Thus the linear equations for determining {h(n)} from {H(k+α)} are considerably simplified.

8. The major advantage of designing a linear phase FIR filter using the frequency sampling method lies in the efficient frequency sampling structure.

A. True
B. False

Although the frequency sampling method provides us with another means for designing linear phase FIR filters, its major advantage lies in the efficient frequency sampling structure, which is obtained when most of the frequency samples are zero.

9. Which of the following is introduced in the frequency sampling realization of the FIR filter?

A. Poles are more in number on the unit circle
B. Zeros are more in number on the unit circle
C. Poles and zeros at equally spaced points on the unit circle
D. None of the mentioned

There is a potential problem with the frequency sampling realization of the FIR linear phase filter. The frequency sampling realization of the FIR filter introduces poles and zeros at equally spaced points on the unit circle.

10. In a practical implementation of the frequency sampling realization, quantization effects preclude a perfect cancellation of the poles and zeros.

A. True
B. False