What is the expression for cutoff frequency in terms of stop band gain?

\(\frac{\Omega_S}{(10^{-K_S/10}-1)^{1/2N}}\)

\(\frac{\Omega_S}{(10^{-K_S/10}+1)^{1/2N}}\)

\(\frac{\Omega_S}{(10^{K_S/10}-1)^{1/2N}}\)

What is the expression for cutoff frequency in terms of pass band gain?

\(\frac{\Omega_P}{(10^{-K_P/10}+1)^{1/2N}}\)

\(\frac{\Omega_P}{(10^{-K_P/10}-1)^{1/2N}}\)

\(\frac{\Omega_P}{(10^{-K_P/10}+1)^{1/2N}}\)

\(\frac{\Omega_P}{(10^{K_P/10}-1)^{1/2N}}\)

What is the order N of the low pass Butterworth filter in terms of KP and KS?

\(\frac{log⁡[(10^\frac{K_P}{10}-1)/(10^\frac{K_s}{10}-1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)

\(\frac{log⁡[(10^\frac{K_P}{10}+1)/(10^\frac{K_s}{10}+1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)

\(\frac{log⁡[(10^\frac{-K_P}{10}+1)/(10^\frac{-K_s}{10}+1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)

\(\frac{log⁡[(10^\frac{-K_P}{10}-1)/(10^\frac{-K_s}{10}-1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)

What is the value of gain at the stop band frequency, i.e., what is the value of KS?

-10 \(log⁡[1-(\frac{\Omega_S}{\Omega_C})^{2N}]\)

-10 \(log⁡[1+(\frac{\Omega_S}{\Omega_C})^{2N}]\)

-10 \(log⁡[1-(\frac{\Omega_S}{\Omega_C})^{2N}]\)

10 \(log⁡[1-(\frac{\Omega_S}{\Omega_C})^{2N}]\)

10 \(log⁡[1+(\frac{\Omega_S}{\Omega_C})^{2N}]\)

What is the value of gain at the pass band frequency, i.e., what is the value of KP?

10 \(log⁡ [1-(\frac{\Omega_P}{\Omega_C})^{2N}]\)

-10 \(log⁡ [1-(\frac{\Omega_P}{\Omega_C})^{2N}]\)

-10 \(log⁡ [1+(\frac{\Omega_P}{\Omega_C})^{2N}]\)

10 \(log⁡ [1-(\frac{\Omega_P}{\Omega_C})^{2N}]\)

10 \(log⁡ [1+(\frac{\Omega_P}{\Omega_C})^{2N}]\)

Explore topic-wise MCQs in Digital Signal Processing.

This section includes 8 Mcqs, each offering curated multiple-choice questions to sharpen your Digital Signal Processing knowledge and support exam preparation. Choose a topic below to get started.

1.	What is the lowest order of the Butterworth filter with a pass band gain KP=-1 dB at ΩP=4 rad/sec and stop band attenuation greater than or equal to 20dB at ΩS = 8 rad/sec?
A.	4
B.	5
C.	6
D.	3
Answer» C. 6

Discussion

2.	The cutoff frequency of the low pass Butterworth filter is the arithmetic mean of the two cutoff frequencies as found above.
A.	True
B.	False
Answer» B. False

Discussion

3.	What is the expression for cutoff frequency in terms of stop band gain?
A.	\(\frac{\Omega_S}{(10^{-K_S/10}-1)^{1/2N}}\)
B.	\(\frac{\Omega_S}{(10^{-K_S/10}+1)^{1/2N}}\)
C.	\(\frac{\Omega_S}{(10^{K_S/10}-1)^{1/2N}}\)
D.	None of the mentioned
Answer» D. None of the mentioned

Discussion

4.	What is the expression for cutoff frequency in terms of pass band gain?
A.	\(\frac{\Omega_P}{(10^{-K_P/10}-1)^{1/2N}}\)
B.	\(\frac{\Omega_P}{(10^{-K_P/10}+1)^{1/2N}}\)
C.	\(\frac{\Omega_P}{(10^{K_P/10}-1)^{1/2N}}\)
D.	None of the mentioned
Answer» B. \(\frac{\Omega_P}{(10^{-K_P/10}+1)^{1/2N}}\)

Discussion

5.	What is the order N of the low pass Butterworth filter in terms of KP and KS?
A.	\(\frac{log⁡[(10^\frac{K_P}{10}-1)/(10^\frac{K_s}{10}-1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)
B.	\(\frac{log⁡[(10^\frac{K_P}{10}+1)/(10^\frac{K_s}{10}+1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)
C.	\(\frac{log⁡[(10^\frac{-K_P}{10}+1)/(10^\frac{-K_s}{10}+1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)
D.	\(\frac{log⁡[(10^\frac{-K_P}{10}-1)/(10^\frac{-K_s}{10}-1)]}{2 log⁡(\frac{\Omega_P}{\Omega_S})}\)
Answer» E.

Discussion

6.	What is the value of gain at the stop band frequency, i.e., what is the value of KS?
A.	-10 \(log⁡[1+(\frac{\Omega_S}{\Omega_C})^{2N}]\)
B.	-10 \(log⁡[1-(\frac{\Omega_S}{\Omega_C})^{2N}]\)
C.	10 \(log⁡[1-(\frac{\Omega_S}{\Omega_C})^{2N}]\)
D.	10 \(log⁡[1+(\frac{\Omega_S}{\Omega_C})^{2N}]\)
Answer» B. -10 \(log⁡[1-(\frac{\Omega_S}{\Omega_C})^{2N}]\)

Discussion

7.	What is the value of gain at the pass band frequency, i.e., what is the value of KP?
A.	-10 \(log⁡ [1-(\frac{\Omega_P}{\Omega_C})^{2N}]\)
B.	-10 \(log⁡ [1+(\frac{\Omega_P}{\Omega_C})^{2N}]\)
C.	10 \(log⁡ [1-(\frac{\Omega_P}{\Omega_C})^{2N}]\)
D.	10 \(log⁡ [1+(\frac{\Omega_P}{\Omega_C})^{2N}]\)
Answer» C. 10 \(log⁡ [1-(\frac{\Omega_P}{\Omega_C})^{2N}]\)

Discussion

8.	Which of the following is a frequency domain specification?
A.	0 ≥ 20 log\|H(jΩ)\|
B.	20 log\|H(jΩ)\| ≥ KP
C.	20 log\|H(jΩ)\| ≤ KS
D.	All of the mentioned
Answer» E.

Discussion

Explore topic-wise MCQs in Digital Signal Processing.

What is the lowest order of the Butterworth filter with a pass band gain KP=-1 dB at ΩP=4 rad/sec and stop band attenuation greater than or equal to 20dB at ΩS = 8 rad/sec?

The cutoff frequency of the low pass Butterworth filter is the arithmetic mean of the two cutoff frequencies as found above.

What is the expression for cutoff frequency in terms of stop band gain?

What is the expression for cutoff frequency in terms of pass band gain?

What is the order N of the low pass Butterworth filter in terms of KP and KS?

What is the value of gain at the stop band frequency, i.e., what is the value of KS?

What is the value of gain at the pass band frequency, i.e., what is the value of KP?

Which of the following is a frequency domain specification?