The value of Z1‘ in terms of Z1, Z2 from the circuits shown below is?

Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z1(Z1 4 m/(1-m2))

Z1‘=(m Z2(Z2 4 m)/(1-m2))/m Z1(Z2 4 m/(1-m2))

Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z2(Z2 4 m/(1-m2))

Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z1(Z2 4 m/(1-m2))

Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z1(Z1 4 m/(1-m2))

The expression of m of the m-derived low pass filter is?

m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-(fc/f)2 )

m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+(fc/fr)2 )

m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+(fc/f)2)

m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-(fc/fr)2 )

m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-(fc/f)2 )

The resonant frequency of m-derived low pass filter in terms of the cut-off frequency of low pass filter is?

fc/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+m2 )

fc/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-m2 )

fc/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+m2 )

fc/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-m2 ))

fc/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+m2 ))

The cut-off frequency of the low pass filter is?

1/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇL

1/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇLC

1/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇLC)

1/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇL

1/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇL)

The value of resonant frequency in the m-derived low pass filter is?

fr=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(LC(1+m2 ) ))

fr=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(‚âà√¨‚àö√ëLC(1+m2 ) ))

fr=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(LC(1-m2 ) ))

fr=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(‚âà√¨‚àö√ëLC(1-m2 ) ))

The value of Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§ in terms of Z1, Z2 from the circuits shown in question 3 is?$

Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§=(m Z1(Z2 4 m)/(1-m2 ))/m Z1(Z1 4 m/(1-m2 ))

Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§=(m Z2(Z2 4 m)/(1-m2 ))/m Z1(Z2 4 m/(1-m2 ))

Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§=(m Z1(Z2 4 m)/(1-m2 ))/m Z2(Z2 4 m/(1-m2 ))

Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§=(m Z1(Z2 4 m)/(1-m2 ))/m Z1(Z2 4 m/(1-m2 ))

Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§=(m Z1(Z2 4 m)/(1-m2 ))/m Z1(Z1 4 m/(1-m2 ))

The value of Z2‚Äö√Ñ√∂‚àö√ë‚àö¬• in terms of Z1, Z2 from the circuits shown in question 1 is?$

Z2‚Äö√Ñ√∂‚àö√ë‚àö‚â§=Z2/4 m (1-m2 )+Z2/m

Z2‚Äö√Ñ√∂‚àö√ë‚àö‚â§=Z1/4 m (1-m2 )+Z1/m

Z2‚Äö√Ñ√∂‚àö√ë‚àö‚â§=Z2/4 m (1-m2 )+Z1/m

Z2‚Äö√Ñ√∂‚àö√ë‚àö‚â§=Z1/4 m (1-m2 )+Z2/m

14 + Mcqs in M Derived T Section in Network Theory Page 1 McqOptions

1.	Given a m-derived low pass filter has cut-off frequency 1 kHz, design impedance of 400Ω and the resonant frequency of 1100 Hz. Find the value of m.
A.	0.216
B.	0.316
C.	0.416
D.	0.516
Answer» D. 0.516

Discussion

2.	Given a m-derived low pass filter has cut-off frequency 1 kHz, design impedance of 400Ω and the resonant frequency of 1100 Hz. Find the value of k.
A.	400
B.	1000
C.	1100
D.	2100
Answer» B. 1000

Discussion

3.	The value of Z1‘ in terms of Z1, Z2 from the circuits shown below is?
A.	Z1‘=(m Z2(Z2 4 m)/(1-m2))/m Z1(Z2 4 m/(1-m2))
B.	Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z2(Z2 4 m/(1-m2))
C.	Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z1(Z2 4 m/(1-m2))
D.	Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z1(Z1 4 m/(1-m2))
Answer» D. Z1‘=(m Z1(Z2 4 m)/(1-m2))/m Z1(Z1 4 m/(1-m2))

Discussion

4.	The relation between Zoπ and Zoπ’ in the circuits shown below is?
A.	Zoπ = 2 Zoπ’
B.	Zoπ = 4 Zoπ’
C.	Zoπ = Zoπ’
D.	Zoπ = 3 Zoπ’
Answer» D. Zoπ = 3 Zoπ’

Discussion

5.	The value of Z2’ in terms of Z1, Z2 from the circuits shown below is?
A.	Z2‘=Z2/4 m (1-m2)+Z2/m
B.	Z2‘=Z1/4 m (1-m2)+Z1/m
C.	Z2‘=Z2/4 m (1-m2)+Z1/m
D.	Z2‘=Z1/4 m (1-m2)+Z2/m
Answer» E.

Discussion

6.	The relation between ZoT and ZoT‘ in the circuits shown below.
A.	ZoT = ZoT‘
B.	ZoT = 2 ZoT‘
C.	ZoT = 3 ZoT‘
D.	ZoT = 4 ZoT‘View Answer
Answer» B. ZoT = 2 ZoT‘

Discussion

7.	GIVEN_A_M-DERIVED_LOW_PASS_FILTER_HAS_CUT-OFF_FREQUENCY_1_KHZ,_DESIGN_IMPEDANCE_OF_400‚ÄÖ√Ñ√∂‚ÀÖ√´¬¨‚ÀÇ_AND_THE_RESONANT_FREQUENCY_OF_1100_HZ._FIND_THE_VALUE_OF_K.?$#
A.	400
B.	1000
C.	1100
D.	2100
Answer» B. 1000

Discussion

8.	The_value_of_m_from_the_information_provided_in_question_9.$
A.	0.216
B.	0.316
C.	0.416
D.	0.516
Answer» D. 0.516

Discussion

9.	The expression of m of the m-derived low pass filter is?
A.	m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+(f<sub>c</sub>/f<sub>r</sub>)<sup>2</sup> )
B.	m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+(f<sub>c</sub>/f)<sup>2</sup>)
C.	m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-(f<sub>c</sub>/f<sub>r</sub>)<sup>2</sup> )
D.	m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-(f<sub>c</sub>/f)<sup>2</sup> )
Answer» D. m=‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-(f<sub>c</sub>/f)<sup>2</sup> )

Discussion

10.	The resonant frequency of m-derived low pass filter in terms of the cut-off frequency of low pass filter is?
A.	f<sub>c</sub>/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-m<sup>2</sup> )
B.	f<sub>c</sub>/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+m<sup>2</sup> )
C.	f<sub>c</sub>/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1-m<sup>2</sup> ))
D.	f<sub>c</sub>/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+m<sup>2</sup> ))
Answer» B. f<sub>c</sub>/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(1+m<sup>2</sup> )

Discussion

11.	The cut-off frequency of the low pass filter is?
A.	1/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇLC
B.	1/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇLC)
C.	1/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇL
D.	1/(‚âà√¨‚àö√ë‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇL)
Answer» C. 1/‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇL

Discussion

12.	The value of resonant frequency in the m-derived low pass filter is?
A.	f<sub>r</sub>=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(LC(1+m<sup>2</sup> ) ))
B.	f<sub>r</sub>=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(‚âà√¨‚àö√ëLC(1+m<sup>2</sup> ) ))
C.	f<sub>r</sub>=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(LC(1-m<sup>2</sup> ) ))
D.	f<sub>r</sub>=1/(‚Äö√Ñ√∂‚àö‚Ä†‚àö‚àÇ(‚âà√¨‚àö√ëLC(1-m<sup>2</sup> ) ))
Answer» E.

Discussion

13.	The value of Z₁^{‚Äö√Ñ√∂‚àö√ë‚àö‚â§} in terms of Z₁, Z₂ from the circuits shown in question 3 is?$
A.	Z<sub>1</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=(m Z<sub>2</sub>(Z<sub>2</sub> 4 m)/(1-m<sup>2</sup> ))/m Z<sub>1</sub>(Z<sub>2</sub> 4 m/(1-m<sup>2</sup> ))
B.	Z<sub>1</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=(m Z<sub>1</sub>(Z<sub>2</sub> 4 m)/(1-m<sup>2</sup> ))/m Z<sub>2</sub>(Z<sub>2</sub> 4 m/(1-m<sup>2</sup> ))
C.	Z<sub>1</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=(m Z<sub>1</sub>(Z<sub>2</sub> 4 m)/(1-m<sup>2</sup> ))/m Z<sub>1</sub>(Z<sub>2</sub> 4 m/(1-m<sup>2</sup> ))
D.	Z<sub>1</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=(m Z<sub>1</sub>(Z<sub>2</sub> 4 m)/(1-m<sup>2</sup> ))/m Z<sub>1</sub>(Z<sub>1</sub> 4 m/(1-m<sup>2</sup> ))
Answer» D. Z<sub>1</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=(m Z<sub>1</sub>(Z<sub>2</sub> 4 m)/(1-m<sup>2</sup> ))/m Z<sub>1</sub>(Z<sub>1</sub> 4 m/(1-m<sup>2</sup> ))

Discussion

14.	The value of Z₂^{‚Äö√Ñ√∂‚àö√ë‚àö¬•} in terms of Z₁, Z₂ from the circuits shown in question 1 is?$
A.	Z<sub>2</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=Z<sub>2</sub>/4 m (1-m<sup>2</sup> )+Z<sub>2</sub>/m
B.	Z<sub>2</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=Z<sub>1</sub>/4 m (1-m<sup>2</sup> )+Z<sub>1</sub>/m
C.	Z<sub>2</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=Z<sub>2</sub>/4 m (1-m<sup>2</sup> )+Z<sub>1</sub>/m
D.	Z<sub>2</sub><sup>‚Äö√Ñ√∂‚àö√ë‚àö‚â§</sup>=Z<sub>1</sub>/4 m (1-m<sup>2</sup> )+Z<sub>2</sub>/m
Answer» E.

Discussion

Explore topic-wise MCQs in Network Theory.

Given a m-derived low pass filter has cut-off frequency 1 kHz, design impedance of 400Ω and the resonant frequency of 1100 Hz. Find the value of m.

Given a m-derived low pass filter has cut-off frequency 1 kHz, design impedance of 400Ω and the resonant frequency of 1100 Hz. Find the value of k.

The value of Z1‘ in terms of Z1, Z2 from the circuits shown below is?

The relation between Zoπ and Zoπ’ in the circuits shown below is?

The value of Z2’ in terms of Z1, Z2 from the circuits shown below is?

The relation between ZoT and ZoT‘ in the circuits shown below.

GIVEN_A_M-DERIVED_LOW_PASS_FILTER_HAS_CUT-OFF_FREQUENCY_1_KHZ,_DESIGN_IMPEDANCE_OF_400‚ÄÖ√Ñ√∂‚ÀÖ√´¬¨‚ÀÇ_AND_THE_RESONANT_FREQUENCY_OF_1100_HZ._FIND_THE_VALUE_OF_K.?$#

The_value_of_m_from_the_information_provided_in_question_9.$

The expression of m of the m-derived low pass filter is?

The resonant frequency of m-derived low pass filter in terms of the cut-off frequency of low pass filter is?

The cut-off frequency of the low pass filter is?

The value of resonant frequency in the m-derived low pass filter is?

The value of Z1‚Äö√Ñ√∂‚àö√ë‚àö‚â§ in terms of Z1, Z2 from the circuits shown in question 3 is?$

The value of Z2‚Äö√Ñ√∂‚àö√ë‚àö¬• in terms of Z1, Z2 from the circuits shown in question 1 is?$

The value of Z₁^{‚Äö√Ñ√∂‚àö√ë‚àö‚â§} in terms of Z₁, Z₂ from the circuits shown in question 3 is?$

The value of Z₂^{‚Äö√Ñ√∂‚àö√ë‚àö¬•} in terms of Z₁, Z₂ from the circuits shown in question 1 is?$