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PHXI15:WAVES

355100 A sonometer wire resonates with a given tuning fork forming five antinodes in the presence of mass $9 k g$ . When this mass is replaced by a mass $M$ , the wire resonates with the same tuning fork forming three antinodes for the same positions of the bridges. The value of $M$ is:

1

25 k g

2

5 k g

3

12.5 k g

4

(1 / 25) k g

Explanation:

In both cases frequencies must be same as same tunning fork is used.
$f_{0} = \frac{5}{2 l} \sqrt{\frac{9 g}{μ}} = \frac{3}{2 l} \sqrt{\frac{M g}{μ}}$
$∴ M = 25 k g$

PHXI15:WAVES

355101 A sonometer wire of length $114 c m$ fixed at both the ends. Where should the two bridges be placed so as to divide the wire into three segments whose fundamental frequencies are in the ratio $1 : 3 : 4$ ?

1 At

36 c m

and

84 c m

from one end

2 At

24 c m

and

72 c m

from one end

3 At

48 c m

and

96 c m

from one end

4 At

72 c m

and

96 c m

) from one end

Explanation:

Total length of the wire, $L = 114 c m$
$f_{1} : f_{2} : f_{3} = 1 : 3 : 4$
Let $L_{1}, L_{2}$ and $L_{3}$ be the lengths of the three parts
$As n α \frac{1}{L}$
$∴ L_{1} : L_{2} : L_{3} = \frac{1}{1} : \frac{1}{3} : \frac{1}{4} = 12 : 4 : 3$
$∴ L_{1} = (\frac{12}{12 + 4 + 3} \times 114) = 72 c m$
$L_{2} = (\frac{4}{19} \times 114) = 24 c m$
$L_{3} = (\frac{3}{19} \times 114) = 18 c m$
Hence the bridges should be placed at $72 c m$ and $72 + 24 = 96 c m$ from one end.

JEE - 2013

PHXI15:WAVES

355102 The given diagram shows three light pieces of paper placed on a wire that is stretched over two supports, $Q$ and $R$ , a distance $4 x$ apart. When the wire is made to vibrate at a particular frequency, all the pieces of paper, except the middle one, fall off the wire. Which of the following could be the wavelength of the vibration?
supporting img

1

2 x

2

3 x

3

4 x

4

8 x

Explanation:

Middle paper does not fall.
So there must be a node at the middle.
The standing wave pattern is
supporting img

$4 x = 2 \times \frac{λ}{2} \Rightarrow λ = 4 x .$

PHXI15:WAVES

355103 A brick is hung from a sonometer wire. If the brick is immersed in oil, then frequency of the wire will

1 Increase due to buoyancy

2 Decrease

3 Remains unchanged

4 Increase due to viscosity of oil

Explanation:

$f α \sqrt{T} α \sqrt{effective weight of load}$
Tension in the string decreases because of buyoancy force. So frequency decreases

PHXI15:WAVES

355104 The total length of a sonometer wire between fixed ends is $110 c m$ . Two bridges are placed to divide the length of wire in ratio $6 : 3 : 2$ . The tension in the wire is $400 N$ and the mass per unit length is $0.01 k g / m$ . What is the minimum common frequency with which three parts can vibrate?

1

166 H z

2

1000 H z

3

1100 H z

4

100 H z

Explanation:

$l_{1} : l_{2} : l_{3} = 6 : 3 : 2$
$∴ l_{1} = \frac{6}{11} \times 110 c m = 60 c m, l_{2} = 30 c m, l_{3} = 20 c m$
$v = \sqrt{\frac{T}{μ}} = \sqrt{\frac{400}{0.01}} m / s = 200 m / s$
Now common ratio of the three lengths $l_{1}, l_{2}$ and $l_{3}$ is 10 .
$∴ \frac{λ}{2} = 10 c m \Rightarrow λ = 20 c m$
$∴ f_{min} = \frac{v}{λ} = \frac{200}{20 \times 10^{- 2}} H z = 1000 H z$

JEE - 2014

PHXI15:WAVES

355100 A sonometer wire resonates with a given tuning fork forming five antinodes in the presence of mass $9 k g$ . When this mass is replaced by a mass $M$ , the wire resonates with the same tuning fork forming three antinodes for the same positions of the bridges. The value of $M$ is:

1

25 k g

2

5 k g

3

12.5 k g

4

(1 / 25) k g

Explanation:

In both cases frequencies must be same as same tunning fork is used.
$f_{0} = \frac{5}{2 l} \sqrt{\frac{9 g}{μ}} = \frac{3}{2 l} \sqrt{\frac{M g}{μ}}$
$∴ M = 25 k g$

PHXI15:WAVES

355101 A sonometer wire of length $114 c m$ fixed at both the ends. Where should the two bridges be placed so as to divide the wire into three segments whose fundamental frequencies are in the ratio $1 : 3 : 4$ ?

1 At

36 c m

and

84 c m

from one end

2 At

24 c m

and

72 c m

from one end

3 At

48 c m

and

96 c m

from one end

4 At

72 c m

and

96 c m

) from one end

Explanation:

Total length of the wire, $L = 114 c m$
$f_{1} : f_{2} : f_{3} = 1 : 3 : 4$
Let $L_{1}, L_{2}$ and $L_{3}$ be the lengths of the three parts
$As n α \frac{1}{L}$
$∴ L_{1} : L_{2} : L_{3} = \frac{1}{1} : \frac{1}{3} : \frac{1}{4} = 12 : 4 : 3$
$∴ L_{1} = (\frac{12}{12 + 4 + 3} \times 114) = 72 c m$
$L_{2} = (\frac{4}{19} \times 114) = 24 c m$
$L_{3} = (\frac{3}{19} \times 114) = 18 c m$
Hence the bridges should be placed at $72 c m$ and $72 + 24 = 96 c m$ from one end.

JEE - 2013

PHXI15:WAVES

355102 The given diagram shows three light pieces of paper placed on a wire that is stretched over two supports, $Q$ and $R$ , a distance $4 x$ apart. When the wire is made to vibrate at a particular frequency, all the pieces of paper, except the middle one, fall off the wire. Which of the following could be the wavelength of the vibration?
supporting img

1

2 x

2

3 x

3

4 x

4

8 x

Explanation:

Middle paper does not fall.
So there must be a node at the middle.
The standing wave pattern is
supporting img

$4 x = 2 \times \frac{λ}{2} \Rightarrow λ = 4 x .$

PHXI15:WAVES

355103 A brick is hung from a sonometer wire. If the brick is immersed in oil, then frequency of the wire will

1 Increase due to buoyancy

2 Decrease

3 Remains unchanged

4 Increase due to viscosity of oil

Explanation:

$f α \sqrt{T} α \sqrt{effective weight of load}$
Tension in the string decreases because of buyoancy force. So frequency decreases

PHXI15:WAVES

355104 The total length of a sonometer wire between fixed ends is $110 c m$ . Two bridges are placed to divide the length of wire in ratio $6 : 3 : 2$ . The tension in the wire is $400 N$ and the mass per unit length is $0.01 k g / m$ . What is the minimum common frequency with which three parts can vibrate?

1

166 H z

2

1000 H z

3

1100 H z

4

100 H z

Explanation:

$l_{1} : l_{2} : l_{3} = 6 : 3 : 2$
$∴ l_{1} = \frac{6}{11} \times 110 c m = 60 c m, l_{2} = 30 c m, l_{3} = 20 c m$
$v = \sqrt{\frac{T}{μ}} = \sqrt{\frac{400}{0.01}} m / s = 200 m / s$
Now common ratio of the three lengths $l_{1}, l_{2}$ and $l_{3}$ is 10 .
$∴ \frac{λ}{2} = 10 c m \Rightarrow λ = 20 c m$
$∴ f_{min} = \frac{v}{λ} = \frac{200}{20 \times 10^{- 2}} H z = 1000 H z$

JEE - 2014

PHXI15:WAVES

355100 A sonometer wire resonates with a given tuning fork forming five antinodes in the presence of mass $9 k g$ . When this mass is replaced by a mass $M$ , the wire resonates with the same tuning fork forming three antinodes for the same positions of the bridges. The value of $M$ is:

1

25 k g

2

5 k g

3

12.5 k g

4

(1 / 25) k g

Explanation:

In both cases frequencies must be same as same tunning fork is used.
$f_{0} = \frac{5}{2 l} \sqrt{\frac{9 g}{μ}} = \frac{3}{2 l} \sqrt{\frac{M g}{μ}}$
$∴ M = 25 k g$

PHXI15:WAVES

355101 A sonometer wire of length $114 c m$ fixed at both the ends. Where should the two bridges be placed so as to divide the wire into three segments whose fundamental frequencies are in the ratio $1 : 3 : 4$ ?

1 At

36 c m

and

84 c m

from one end

2 At

24 c m

and

72 c m

from one end

3 At

48 c m

and

96 c m

from one end

4 At

72 c m

and

96 c m

) from one end

Explanation:

Total length of the wire, $L = 114 c m$
$f_{1} : f_{2} : f_{3} = 1 : 3 : 4$
Let $L_{1}, L_{2}$ and $L_{3}$ be the lengths of the three parts
$As n α \frac{1}{L}$
$∴ L_{1} : L_{2} : L_{3} = \frac{1}{1} : \frac{1}{3} : \frac{1}{4} = 12 : 4 : 3$
$∴ L_{1} = (\frac{12}{12 + 4 + 3} \times 114) = 72 c m$
$L_{2} = (\frac{4}{19} \times 114) = 24 c m$
$L_{3} = (\frac{3}{19} \times 114) = 18 c m$
Hence the bridges should be placed at $72 c m$ and $72 + 24 = 96 c m$ from one end.

JEE - 2013

PHXI15:WAVES

355102 The given diagram shows three light pieces of paper placed on a wire that is stretched over two supports, $Q$ and $R$ , a distance $4 x$ apart. When the wire is made to vibrate at a particular frequency, all the pieces of paper, except the middle one, fall off the wire. Which of the following could be the wavelength of the vibration?
supporting img

1

2 x

2

3 x

3

4 x

4

8 x

Explanation:

Middle paper does not fall.
So there must be a node at the middle.
The standing wave pattern is
supporting img

$4 x = 2 \times \frac{λ}{2} \Rightarrow λ = 4 x .$

PHXI15:WAVES

355103 A brick is hung from a sonometer wire. If the brick is immersed in oil, then frequency of the wire will

1 Increase due to buoyancy

2 Decrease

3 Remains unchanged

4 Increase due to viscosity of oil

Explanation:

$f α \sqrt{T} α \sqrt{effective weight of load}$
Tension in the string decreases because of buyoancy force. So frequency decreases

PHXI15:WAVES

355104 The total length of a sonometer wire between fixed ends is $110 c m$ . Two bridges are placed to divide the length of wire in ratio $6 : 3 : 2$ . The tension in the wire is $400 N$ and the mass per unit length is $0.01 k g / m$ . What is the minimum common frequency with which three parts can vibrate?

1

166 H z

2

1000 H z

3

1100 H z

4

100 H z

Explanation:

$l_{1} : l_{2} : l_{3} = 6 : 3 : 2$
$∴ l_{1} = \frac{6}{11} \times 110 c m = 60 c m, l_{2} = 30 c m, l_{3} = 20 c m$
$v = \sqrt{\frac{T}{μ}} = \sqrt{\frac{400}{0.01}} m / s = 200 m / s$
Now common ratio of the three lengths $l_{1}, l_{2}$ and $l_{3}$ is 10 .
$∴ \frac{λ}{2} = 10 c m \Rightarrow λ = 20 c m$
$∴ f_{min} = \frac{v}{λ} = \frac{200}{20 \times 10^{- 2}} H z = 1000 H z$

JEE - 2014

PHXI15:WAVES

355100 A sonometer wire resonates with a given tuning fork forming five antinodes in the presence of mass $9 k g$ . When this mass is replaced by a mass $M$ , the wire resonates with the same tuning fork forming three antinodes for the same positions of the bridges. The value of $M$ is:

1

25 k g

2

5 k g

3

12.5 k g

4

(1 / 25) k g

Explanation:

In both cases frequencies must be same as same tunning fork is used.
$f_{0} = \frac{5}{2 l} \sqrt{\frac{9 g}{μ}} = \frac{3}{2 l} \sqrt{\frac{M g}{μ}}$
$∴ M = 25 k g$

PHXI15:WAVES

355101 A sonometer wire of length $114 c m$ fixed at both the ends. Where should the two bridges be placed so as to divide the wire into three segments whose fundamental frequencies are in the ratio $1 : 3 : 4$ ?

1 At

36 c m

and

84 c m

from one end

2 At

24 c m

and

72 c m

from one end

3 At

48 c m

and

96 c m

from one end

4 At

72 c m

and

96 c m

) from one end

Explanation:

Total length of the wire, $L = 114 c m$
$f_{1} : f_{2} : f_{3} = 1 : 3 : 4$
Let $L_{1}, L_{2}$ and $L_{3}$ be the lengths of the three parts
$As n α \frac{1}{L}$
$∴ L_{1} : L_{2} : L_{3} = \frac{1}{1} : \frac{1}{3} : \frac{1}{4} = 12 : 4 : 3$
$∴ L_{1} = (\frac{12}{12 + 4 + 3} \times 114) = 72 c m$
$L_{2} = (\frac{4}{19} \times 114) = 24 c m$
$L_{3} = (\frac{3}{19} \times 114) = 18 c m$
Hence the bridges should be placed at $72 c m$ and $72 + 24 = 96 c m$ from one end.

JEE - 2013

PHXI15:WAVES

355102 The given diagram shows three light pieces of paper placed on a wire that is stretched over two supports, $Q$ and $R$ , a distance $4 x$ apart. When the wire is made to vibrate at a particular frequency, all the pieces of paper, except the middle one, fall off the wire. Which of the following could be the wavelength of the vibration?
supporting img

1

2 x

2

3 x

3

4 x

4

8 x

Explanation:

Middle paper does not fall.
So there must be a node at the middle.
The standing wave pattern is
supporting img

$4 x = 2 \times \frac{λ}{2} \Rightarrow λ = 4 x .$

PHXI15:WAVES

355103 A brick is hung from a sonometer wire. If the brick is immersed in oil, then frequency of the wire will

1 Increase due to buoyancy

2 Decrease

3 Remains unchanged

4 Increase due to viscosity of oil

Explanation:

$f α \sqrt{T} α \sqrt{effective weight of load}$
Tension in the string decreases because of buyoancy force. So frequency decreases

PHXI15:WAVES

355104 The total length of a sonometer wire between fixed ends is $110 c m$ . Two bridges are placed to divide the length of wire in ratio $6 : 3 : 2$ . The tension in the wire is $400 N$ and the mass per unit length is $0.01 k g / m$ . What is the minimum common frequency with which three parts can vibrate?

1

166 H z

2

1000 H z

3

1100 H z

4

100 H z

Explanation:

$l_{1} : l_{2} : l_{3} = 6 : 3 : 2$
$∴ l_{1} = \frac{6}{11} \times 110 c m = 60 c m, l_{2} = 30 c m, l_{3} = 20 c m$
$v = \sqrt{\frac{T}{μ}} = \sqrt{\frac{400}{0.01}} m / s = 200 m / s$
Now common ratio of the three lengths $l_{1}, l_{2}$ and $l_{3}$ is 10 .
$∴ \frac{λ}{2} = 10 c m \Rightarrow λ = 20 c m$
$∴ f_{min} = \frac{v}{λ} = \frac{200}{20 \times 10^{- 2}} H z = 1000 H z$

JEE - 2014

PHXI15:WAVES

355100 A sonometer wire resonates with a given tuning fork forming five antinodes in the presence of mass $9 k g$ . When this mass is replaced by a mass $M$ , the wire resonates with the same tuning fork forming three antinodes for the same positions of the bridges. The value of $M$ is:

1

25 k g

2

5 k g

3

12.5 k g

4

(1 / 25) k g

Explanation:

In both cases frequencies must be same as same tunning fork is used.
$f_{0} = \frac{5}{2 l} \sqrt{\frac{9 g}{μ}} = \frac{3}{2 l} \sqrt{\frac{M g}{μ}}$
$∴ M = 25 k g$

PHXI15:WAVES

355101 A sonometer wire of length $114 c m$ fixed at both the ends. Where should the two bridges be placed so as to divide the wire into three segments whose fundamental frequencies are in the ratio $1 : 3 : 4$ ?

1 At

36 c m

and

84 c m

from one end

2 At

24 c m

and

72 c m

from one end

3 At

48 c m

and

96 c m

from one end

4 At

72 c m

and

96 c m

) from one end

Explanation:

Total length of the wire, $L = 114 c m$
$f_{1} : f_{2} : f_{3} = 1 : 3 : 4$
Let $L_{1}, L_{2}$ and $L_{3}$ be the lengths of the three parts
$As n α \frac{1}{L}$
$∴ L_{1} : L_{2} : L_{3} = \frac{1}{1} : \frac{1}{3} : \frac{1}{4} = 12 : 4 : 3$
$∴ L_{1} = (\frac{12}{12 + 4 + 3} \times 114) = 72 c m$
$L_{2} = (\frac{4}{19} \times 114) = 24 c m$
$L_{3} = (\frac{3}{19} \times 114) = 18 c m$
Hence the bridges should be placed at $72 c m$ and $72 + 24 = 96 c m$ from one end.

JEE - 2013

PHXI15:WAVES

355102 The given diagram shows three light pieces of paper placed on a wire that is stretched over two supports, $Q$ and $R$ , a distance $4 x$ apart. When the wire is made to vibrate at a particular frequency, all the pieces of paper, except the middle one, fall off the wire. Which of the following could be the wavelength of the vibration?
supporting img

1

2 x

2

3 x

3

4 x

4

8 x

Explanation:

Middle paper does not fall.
So there must be a node at the middle.
The standing wave pattern is
supporting img

$4 x = 2 \times \frac{λ}{2} \Rightarrow λ = 4 x .$

PHXI15:WAVES

355103 A brick is hung from a sonometer wire. If the brick is immersed in oil, then frequency of the wire will

1 Increase due to buoyancy

2 Decrease

3 Remains unchanged

4 Increase due to viscosity of oil

Explanation:

$f α \sqrt{T} α \sqrt{effective weight of load}$
Tension in the string decreases because of buyoancy force. So frequency decreases

PHXI15:WAVES

355104 The total length of a sonometer wire between fixed ends is $110 c m$ . Two bridges are placed to divide the length of wire in ratio $6 : 3 : 2$ . The tension in the wire is $400 N$ and the mass per unit length is $0.01 k g / m$ . What is the minimum common frequency with which three parts can vibrate?

1

166 H z

2

1000 H z

3

1100 H z

4

100 H z

Explanation:

$l_{1} : l_{2} : l_{3} = 6 : 3 : 2$
$∴ l_{1} = \frac{6}{11} \times 110 c m = 60 c m, l_{2} = 30 c m, l_{3} = 20 c m$
$v = \sqrt{\frac{T}{μ}} = \sqrt{\frac{400}{0.01}} m / s = 200 m / s$
Now common ratio of the three lengths $l_{1}, l_{2}$ and $l_{3}$ is 10 .
$∴ \frac{λ}{2} = 10 c m \Rightarrow λ = 20 c m$
$∴ f_{min} = \frac{v}{λ} = \frac{200}{20 \times 10^{- 2}} H z = 1000 H z$

JEE - 2014