Home
Class 11
PHYSICS
The equation of a longitudinal stationar...

The equation of a longitudinal stationary wave produced in a closed organ pipe is
`y=6 sin (2pix)/(6) cos 160 pi t`
where x, y are in cm and t in second.Find (i)the frequency , amplitude and wavelength of the original progressive wave (ii)separation between two successive nodes .

Promotional Banner

Topper's Solved these Questions

Similar Questions

Explore conceptually related problems

The equation of stationary wave along a stretched string is given by y=5 sin (pix)/(3) cos 40 pi t , where x and y are in cm and t in second. The separation between two adjacent nodes is

The equation of stationary wave along a stretched string is given by y = 5 sin(pi x)/(3) cos 40pi t where x and y are in centimetre and t in second. The separation between two adjacent nodes is :

The equation of a stationary a stationary wave is represented by y=4sin((pi)/(6))(cos20pit) when x and y are in cm and t is in second. Wavelength of the component waves is

The equation of a wave distrubance is a given as y= 0.02 sin ((pi)/(2)+50pi t) cos (10 pix) , where x and y are in metre and t is in second . Choose the correct statement (s).

The equation given below represents a stationary wave set-up in a medium y=12sin(4pix)sin(4pit) where y and x are in cm and t is in second. Calculate the amplitude, wavelength and velocity of the component waves.

The equation of a stationary wave along a stretched string is given by y = 4 sin frac{2pi"x"}{3} cos 4Opit where, x and y are in cms and t is in sec. The separation between two adjacent nodes is

The equation of a stationary wave is given by y=6sin(pi)//(x)cos40pit Where y and x are given in cm and time t in second. Then the amplitude of progressive wave is

The equation of a stationary wave is given by y=6sin.(2pix)/(3)cos40pit . Where y and x are in cm and time t is in s. In respect to the component progressive waves, calculate (a) amplitude (b) wavelength (c ) frequency

SL ARORA-Waves-EXERCISE
  1. The equation of a longitudinal stationary wave produced in a closed or...

    Text Solution

    |

  2. The equation of a longitudinal stationary wave produced in a closed or...

    Text Solution

    |

  3. The equation of a longitudinal stationary wave produced in a closed or...

    Text Solution

    |

  4. The equation of a longitudinal stationary wave produced in a closed or...

    Text Solution

    |

  5. Write the equation of a wave identical to the wave represented by the ...

    Text Solution

    |

  6. Write the equation of a wave identical to the wave represented by the ...

    Text Solution

    |

  7. Write the equation of a wave identical to the wave represented by the ...

    Text Solution

    |

  8. A sonometer wire is under a tension of 40 N and the length between the...

    Text Solution

    |

  9. A cord 80 cm long is stretched by a load of 8.0 kg f.The mass per unit...

    Text Solution

    |

  10. The length of a stretched wire is 1 m and its fundamental frequency is...

    Text Solution

    |

  11. The mass of 1m long steel wire is 20 g. The wire is stretched under a ...

    Text Solution

    |

  12. If the tension in the string is increased by 5 kg wt, the frequency of...

    Text Solution

    |

  13. A sonometer wire has a length of 114 cm between its two fixed ends. Wh...

    Text Solution

    |

  14. Two wires of the same material are stretched with the same force. Thei...

    Text Solution

    |

  15. A guitar string is 90 cm long and has a fundamental frequency of 124 H...

    Text Solution

    |

  16. The ratio of frequencies of two wires having same length and same tens...

    Text Solution

    |

  17. A 50 cm long wire is in unison with a tuning fork of frequency 256, wh...

    Text Solution

    |

  18. A string vibrates with a frequency of 200Hz. Its length is doubled and...

    Text Solution

    |

  19. In Melde's experiment , a string vibrates in 3 loops when 8 grams were...

    Text Solution

    |

  20. An open organ pipe produces a note of frequency 512 Hz at 15^@ C, calc...

    Text Solution

    |