355710 A body of mass \(1\;kg\) is rotating in a vertical circle of radius \(1\;m.\) what will be the difference in its kinetic energy at the top and bottom of the circle?(take, \(g = 10\;m{s^{ - 2}}\) )

355711 A stone of mass \(1\,kg\) tied on one end of the light string is whirled in vertical circle, as shown in the figure. The tension in the string (in \({N}\)) when the string becomes horizontal is

355712 A particle moves down the inclined surface and completes a vertical circular motion. The ratio of \(H\) and \(h\) is

355713 A body of mass \(m\;kg\) slides from rest along the curve of vertical circle from point \(A\) to \(B\) in frictionless path. The velocity of the body at \(B\) is


(Given : \(R = 14\;m,\) \(g = 10\;m/{s^2}\) and \(\sqrt 2 = 1.4\) )

355714 The mass of a pendulum bob is \(200\) gram and the string is \(2\) metre long. The bob is held so that the string is horizontal, and it is then allowed to fall. The K.E. of the bob when string makes an angle of \(45^{\circ}\) with vertical is
(Take \(g = 10\;m{\rm{/}}{s^2}\) and \(\sqrt{2}=1.41\) )

355710 A body of mass \(1\;kg\) is rotating in a vertical circle of radius \(1\;m.\) what will be the difference in its kinetic energy at the top and bottom of the circle?(take, \(g = 10\;m{s^{ - 2}}\) )

355711 A stone of mass \(1\,kg\) tied on one end of the light string is whirled in vertical circle, as shown in the figure. The tension in the string (in \({N}\)) when the string becomes horizontal is

355712 A particle moves down the inclined surface and completes a vertical circular motion. The ratio of \(H\) and \(h\) is

355713 A body of mass \(m\;kg\) slides from rest along the curve of vertical circle from point \(A\) to \(B\) in frictionless path. The velocity of the body at \(B\) is


(Given : \(R = 14\;m,\) \(g = 10\;m/{s^2}\) and \(\sqrt 2 = 1.4\) )

355714 The mass of a pendulum bob is \(200\) gram and the string is \(2\) metre long. The bob is held so that the string is horizontal, and it is then allowed to fall. The K.E. of the bob when string makes an angle of \(45^{\circ}\) with vertical is
(Take \(g = 10\;m{\rm{/}}{s^2}\) and \(\sqrt{2}=1.41\) )

355710 A body of mass \(1\;kg\) is rotating in a vertical circle of radius \(1\;m.\) what will be the difference in its kinetic energy at the top and bottom of the circle?(take, \(g = 10\;m{s^{ - 2}}\) )

355711 A stone of mass \(1\,kg\) tied on one end of the light string is whirled in vertical circle, as shown in the figure. The tension in the string (in \({N}\)) when the string becomes horizontal is

355712 A particle moves down the inclined surface and completes a vertical circular motion. The ratio of \(H\) and \(h\) is

355713 A body of mass \(m\;kg\) slides from rest along the curve of vertical circle from point \(A\) to \(B\) in frictionless path. The velocity of the body at \(B\) is


(Given : \(R = 14\;m,\) \(g = 10\;m/{s^2}\) and \(\sqrt 2 = 1.4\) )

355714 The mass of a pendulum bob is \(200\) gram and the string is \(2\) metre long. The bob is held so that the string is horizontal, and it is then allowed to fall. The K.E. of the bob when string makes an angle of \(45^{\circ}\) with vertical is
(Take \(g = 10\;m{\rm{/}}{s^2}\) and \(\sqrt{2}=1.41\) )

355710 A body of mass \(1\;kg\) is rotating in a vertical circle of radius \(1\;m.\) what will be the difference in its kinetic energy at the top and bottom of the circle?(take, \(g = 10\;m{s^{ - 2}}\) )

355711 A stone of mass \(1\,kg\) tied on one end of the light string is whirled in vertical circle, as shown in the figure. The tension in the string (in \({N}\)) when the string becomes horizontal is

355712 A particle moves down the inclined surface and completes a vertical circular motion. The ratio of \(H\) and \(h\) is

355713 A body of mass \(m\;kg\) slides from rest along the curve of vertical circle from point \(A\) to \(B\) in frictionless path. The velocity of the body at \(B\) is


(Given : \(R = 14\;m,\) \(g = 10\;m/{s^2}\) and \(\sqrt 2 = 1.4\) )

355714 The mass of a pendulum bob is \(200\) gram and the string is \(2\) metre long. The bob is held so that the string is horizontal, and it is then allowed to fall. The K.E. of the bob when string makes an angle of \(45^{\circ}\) with vertical is
(Take \(g = 10\;m{\rm{/}}{s^2}\) and \(\sqrt{2}=1.41\) )

355710 A body of mass \(1\;kg\) is rotating in a vertical circle of radius \(1\;m.\) what will be the difference in its kinetic energy at the top and bottom of the circle?(take, \(g = 10\;m{s^{ - 2}}\) )

355711 A stone of mass \(1\,kg\) tied on one end of the light string is whirled in vertical circle, as shown in the figure. The tension in the string (in \({N}\)) when the string becomes horizontal is

355712 A particle moves down the inclined surface and completes a vertical circular motion. The ratio of \(H\) and \(h\) is

355713 A body of mass \(m\;kg\) slides from rest along the curve of vertical circle from point \(A\) to \(B\) in frictionless path. The velocity of the body at \(B\) is


(Given : \(R = 14\;m,\) \(g = 10\;m/{s^2}\) and \(\sqrt 2 = 1.4\) )

355714 The mass of a pendulum bob is \(200\) gram and the string is \(2\) metre long. The bob is held so that the string is horizontal, and it is then allowed to fall. The K.E. of the bob when string makes an angle of \(45^{\circ}\) with vertical is
(Take \(g = 10\;m{\rm{/}}{s^2}\) and \(\sqrt{2}=1.41\) )