Cengage NEET by C.P Singh

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A transverse sinusoidal wave of amplitude a, wavelength λ and frequency f is travelling on a stretched string. The maximum speed of any point on the string is u/10, where n is the speed of propagation of the wave. If a =10^−3 m and v=10 m/s, then λ and f are given by.
16
Sep
A transverse sinusoidal wave of amplitude a, wavelength λ and frequency f is travelling on a stretched string. The maximum speed of any point on the string is u/10, where n is the speed of propagation of the wave. If a =10^−3 m and v=10 m/s, then λ and f are given by. A transverse [...]
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: A transverse sinusoidal wave of amplitude a , then λ and f are given by. , wavelength λ and frequency f is travelling on a stretched string. The maximum speed of any point on the string is u/10 , where n is the speed of propagation of the wave. If a =10^−3 m and v=10 m/s ,
A wave travelling along the x-axis is described by the equation v(x,t)=0.005 cos (αx−βt). If the wavelength and the time period of the wave are 0.08m and 2.0s, respectively, then α and β in appropriate units are
16
Sep
A wave travelling along the x-axis is described by the equation v(x,t)=0.005 cos (αx−βt). If the wavelength and the time period of the wave are 0.08m and 2.0s, respectively, then α and β in appropriate units are A wave travelling along the x-axis is described by the equation v(x respectively t)=0.005 cos (αx−βt). If the [...]
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: A wave travelling along the x-axis is described by the equation v(x , respectively , t)=0.005 cos (αx−βt). If the wavelength and the time period of the wave are 0.08m and 2.0s , then α and β in appropriate units are ,
A wave is represented by the equation y=(0.001)sin ( 50 t + 2 x ) where x in metre, t in sec and y in mm
16
Sep
A wave is represented by the equation y=(0.001)sin ( 50 t + 2 x ) where x in metre, t in sec and y in mm A wave is represented by the equation y=(0.001)sin ( 50 t + 2 x ) where x in metre t in sec and y in mm September 16, 2020 [...]
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: A wave is represented by the equation y=(0.001)sin ( 50 t + 2 x ) where x in metre , t in sec and y in mm ,
The equation y=A cos^2(2π nt − 2π x/λ) represents a wave with
16
Sep
The equation y=A cos^2(2π nt − 2π x/λ) represents a wave with The equation y=A cos^2(2π nt − 2π x/λ) represents a wave with September 16, 2020 Category: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: The equation y=A cos^2(2π nt − 2π x/λ) represents a wave with ,
The function sin^2 ( wt ) represents
16
Sep
The function sin^2 ( wt ) represents The function sin^2 ( wt ) represents September 16, 2020 Category: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: The function sin^2 ( wt ) represents ,
A progressive sound wave of frequency 500 Hz is travelling with a speed of 350ms^−1. A compression maximum appears at a place at a given instant. The minimum time interval after which the rarefaction maximum occurs at the same point is.
16
Sep
A progressive sound wave of frequency 500 Hz is travelling with a speed of 350ms^−1. A compression maximum appears at a place at a given instant. The minimum time interval after which the rarefaction maximum occurs at the same point is. in a previous question the minimum distance between a centre of compression and a [...]
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: in a previous question the minimum distance between a centre of compression and a centre of rarefaction at any instant is ,
in a previous question the minimum distance between a centre of compression and a centre of rarefaction at any instant is
16
Sep
in a previous question the minimum distance between a centre of compression and a centre of rarefaction at any instant is in a previous question the minimum distance between a centre of compression and a centre of rarefaction at any instant is September 16, 2020 Category: Cengage NEET by C.P Singh , Chapter 16 - [...]
Posted in: Cengage NEET by C.P Singh , Chapter 16 - Wave Motion and Waves on a String , Part 1 ,
Tags: in a previous question the minimum distance between a centre of compression and a centre of rarefaction at any instant is ,
A vertical glass capillary tube, open at both ends, contains some water. Which of the following shapes may not be taken by the water in the tube?
16
Sep
A vertical glass capillary tube, open at both ends, contains some water. Which of the following shapes may not be taken by the water in the tube? A vertical glass capillary tube contains some water. Which of the following shapes may not be taken by the water in the tube? open at both ends September [...]
Posted in: Cengage NEET by C.P Singh , Chapter 14 - Fluid Mechanics , Part 1 ,
Tags: A vertical glass capillary tube , contains some water. Which of the following shapes may not be taken by the water in the tube? , open at both ends ,
If a water drop is kept between two glass plates, then its shape is
16
Sep
If a water drop is kept between two glass plates, then its shape is If a water drop is kept between two glass plates then its shape is September 16, 2020 Category: Cengage NEET by C.P Singh , Chapter 14 - Fluid Mechanics , Part 1 ,
Posted in: Cengage NEET by C.P Singh , Chapter 14 - Fluid Mechanics , Part 1 ,
Tags: If a water drop is kept between two glass plates , then its shape is ,
A vessel, whose bottom has round holes with diameter of 0.1 mm , is filled with water. The maximum height to which the water can be filled without leakage is (S.T. of water =75 dyne/cm , g=1000 cm/s^2)
16
Sep
A vessel, whose bottom has round holes with diameter of 0.1 mm , is filled with water. The maximum height to which the water can be filled without leakage is (S.T. of water =75 dyne/cm , g=1000 cm/s^2) A vessel g=1000 cm/s^2) is filled with water. The maximum height to which the water can be [...]
Posted in: Cengage NEET by C.P Singh , Chapter 14 - Fluid Mechanics , Part 1 ,
Tags: A vessel , g=1000 cm/s^2) , is filled with water. The maximum height to which the water can be filled without leakage is (S.T. of water =75 dyne/cm , whose bottom has round holes with diameter of 0.1 mm ,