266439 When a resistance 2 ohm is placed across a battery the current is 1 A and when the resistance across the terminal is 17 ohm , the current is 0.25 A . The emf of the battery is-

266440 Velocity of a body is expressed as \(V=G^9 M^b R^c\) where \(G\) is funiversal gravitational constant, \(M\) is mass and R is radius. Then values of \(a, b, c\) is respectively:

266441 The displacement equation of a particle performing SHM is given by \(x=4 \sin \frac{\pi}{2} \mathrm{t}\). The ratio of displacement and distance traveled in first second

266442 Acceleration a versus position \(x\) and potenitial energy \(U\) versus position \(x\) graph of a particle of mass 1 kg moving along \(x\)-axis are shown in figure. Assume that at \(x=0\), the velocity of the particle is 4 ms match the following at \(x=8 \mathrm{~m}\) |Column - I|Column- 11| |-------|------| |(A) Kinetic energy|(P) 120.| |(B) Work done by conservative force|(Q) 240 J| |(C) Total work done|(R) 128 J| |(D) Work done by external forces|(S) 112 J| | | (T) None|

266439 When a resistance 2 ohm is placed across a battery the current is 1 A and when the resistance across the terminal is 17 ohm , the current is 0.25 A . The emf of the battery is-

266440 Velocity of a body is expressed as \(V=G^9 M^b R^c\) where \(G\) is funiversal gravitational constant, \(M\) is mass and R is radius. Then values of \(a, b, c\) is respectively:

266441 The displacement equation of a particle performing SHM is given by \(x=4 \sin \frac{\pi}{2} \mathrm{t}\). The ratio of displacement and distance traveled in first second

266442 Acceleration a versus position \(x\) and potenitial energy \(U\) versus position \(x\) graph of a particle of mass 1 kg moving along \(x\)-axis are shown in figure. Assume that at \(x=0\), the velocity of the particle is 4 ms match the following at \(x=8 \mathrm{~m}\) |Column - I|Column- 11| |-------|------| |(A) Kinetic energy|(P) 120.| |(B) Work done by conservative force|(Q) 240 J| |(C) Total work done|(R) 128 J| |(D) Work done by external forces|(S) 112 J| | | (T) None|

266439 When a resistance 2 ohm is placed across a battery the current is 1 A and when the resistance across the terminal is 17 ohm , the current is 0.25 A . The emf of the battery is-

266440 Velocity of a body is expressed as \(V=G^9 M^b R^c\) where \(G\) is funiversal gravitational constant, \(M\) is mass and R is radius. Then values of \(a, b, c\) is respectively:

266441 The displacement equation of a particle performing SHM is given by \(x=4 \sin \frac{\pi}{2} \mathrm{t}\). The ratio of displacement and distance traveled in first second

266442 Acceleration a versus position \(x\) and potenitial energy \(U\) versus position \(x\) graph of a particle of mass 1 kg moving along \(x\)-axis are shown in figure. Assume that at \(x=0\), the velocity of the particle is 4 ms match the following at \(x=8 \mathrm{~m}\) |Column - I|Column- 11| |-------|------| |(A) Kinetic energy|(P) 120.| |(B) Work done by conservative force|(Q) 240 J| |(C) Total work done|(R) 128 J| |(D) Work done by external forces|(S) 112 J| | | (T) None|

266439 When a resistance 2 ohm is placed across a battery the current is 1 A and when the resistance across the terminal is 17 ohm , the current is 0.25 A . The emf of the battery is-

266440 Velocity of a body is expressed as \(V=G^9 M^b R^c\) where \(G\) is funiversal gravitational constant, \(M\) is mass and R is radius. Then values of \(a, b, c\) is respectively:

266441 The displacement equation of a particle performing SHM is given by \(x=4 \sin \frac{\pi}{2} \mathrm{t}\). The ratio of displacement and distance traveled in first second

266442 Acceleration a versus position \(x\) and potenitial energy \(U\) versus position \(x\) graph of a particle of mass 1 kg moving along \(x\)-axis are shown in figure. Assume that at \(x=0\), the velocity of the particle is 4 ms match the following at \(x=8 \mathrm{~m}\) |Column - I|Column- 11| |-------|------| |(A) Kinetic energy|(P) 120.| |(B) Work done by conservative force|(Q) 240 J| |(C) Total work done|(R) 128 J| |(D) Work done by external forces|(S) 112 J| | | (T) None|