Cengage NEET by C.P Singh

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If the kinetic energy of body is directly proportional to time t, the magnitude of force acting on the body is (i) directly proportional to t√ (ii) inversely proportional to t√ (iii) directly proportional to the speed of the body. (iv) inversely proportional to the speed of the body.
21
Oct
If the kinetic energy of body is directly proportional to time t, the magnitude of force acting on the body is (i) directly proportional to t√ (ii) inversely proportional to t√ (iii) directly proportional to the speed of the body. (iv) inversely proportional to the speed of the body. If the kinetic energy of body [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: If the kinetic energy of body is directly proportional to time t , Work done from d = 0 m to d = 3 m ,
The kinetic energy acquired by a body of mass m in travelling a certain distance starting from rest, under a constant force is:
21
Oct
The kinetic energy acquired by a body of mass m in travelling a certain distance starting from rest, under a constant force is: The kinetic energy acquired by a body of mass m in travelling a certain distance starting from rest under a constant force is: October 21, 2020 Category: Cengage NEET by C.P Singh [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: The kinetic energy acquired by a body of mass m in travelling a certain distance starting from rest , under a constant force is: ,
If the force acting on a body is inversely proportional to its speed, the kinetic energy of the body is
21
Oct
If the force acting on a body is inversely proportional to its speed, the kinetic energy of the body is If the force acting on a body is inversely proportional to its speed the kinetic energy of the body is October 21, 2020 Category: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: If the force acting on a body is inversely proportional to its speed , the kinetic energy of the body is ,
A force acting on particle is given by F = (3x^2i + 4yj])N. The change in kinetic energy of particle as it moves from (0,2m) to (1m, 3m) is a
21
Oct
A force acting on particle is given by F = (3x^2i + 4yj])N. The change in kinetic energy of particle as it moves from (0,2m) to (1m, 3m) is a 2m) to (1m 3m) is a A force acting on particle is given by F = (3x^2i + 4yj])N. The change in kinetic energy of [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: 2m) to (1m , 3m) is a , A force acting on particle is given by F = (3x^2i + 4yj])N. The change in kinetic energy of particle as it moves from (0 ,
Two blocks A and B have masses m and 4m, respectively. Each one is acted upon by a force F. If they acquire the same kinetic energy in time tA and tB, then (tA)/(tB) is
21
Oct
Two blocks A and B have masses m and 4m, respectively. Each one is acted upon by a force F. If they acquire the same kinetic energy in time tA and tB, then (tA)/(tB) is respectively. Each one is acted upon by a force F. If they acquire the same kinetic energy in time tA [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: respectively. Each one is acted upon by a force F. If they acquire the same kinetic energy in time tA and tB , then (tA)/(tB) is , Two blocks A and B have masses m and 4m ,
A block of mass 2 kg is resting on a smooth surface. At what angle a force of 10 N be acting on the block so that it will acquire a kinetic energy of 10 J after moving 2 m
21
Oct
A block of mass 2 kg is resting on a smooth surface. At what angle a force of 10 N be acting on the block so that it will acquire a kinetic energy of 10 J after moving 2 m A block of mass 2 kg is resting on a smooth surface. At what angle [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: A block of mass 2 kg is resting on a smooth surface. At what angle a force of 10 N be acting on the block so that it will acquire a kinetic energy of 10 J after moving 2 m ,
A particle of mass 0.1 kg is subjected to a force which varies with distance as shown in figure. If it starts its journey from rest at x=0, its velocity at x=12m is
21
Oct
A particle of mass 0.1 kg is subjected to a force which varies with distance as shown in figure. If it starts its journey from rest at x=0, its velocity at x=12m is A particle of mass 0.1 kg is subjected to a force which varies with distance as shown in figure. If it starts [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: A particle of mass 0.1 kg is subjected to a force which varies with distance as shown in figure. If it starts its journey from rest at x=0 , its velocity at x=12m is ,
A block of mass m at rest is acted upon by a force F for a time t. The kinetic energy of block after time t is
21
Oct
A block of mass m at rest is acted upon by a force F for a time t. The kinetic energy of block after time t is A block of mass m at rest is acted upon by a force F for a time t. The kinetic energy of block after time t is October [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: A block of mass m at rest is acted upon by a force F for a time t. The kinetic energy of block after time t is ,
A particle is moving along the x-axis and force acting on it is given by F=F0 sinω N, where ω is a constant. The work done by the force from x=0 to x=2 will be
21
Oct
A particle is moving along the x-axis and force acting on it is given by F=F0 sinω N, where ω is a constant. The work done by the force from x=0 to x=2 will be A particle is moving along the x-axis and force acting on it is given by F=F0 sinω N where ω [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: A particle is moving along the x-axis and force acting on it is given by F=F0 sinω N , where ω is a constant. The work done by the force from x=0 to x=2 will be ,
A particle of mass m moves on a straight line with its velocity varying with the distance travelled according to the equation v=ax−−√, where a is a constant. Find the total work done by all the forces during a displacement from x=0→x=d.
21
Oct
A particle of mass m moves on a straight line with its velocity varying with the distance travelled according to the equation v=ax−−√, where a is a constant. Find the total work done by all the forces during a displacement from x=0→x=d. A particle of mass m moves on a straight line with its velocity [...]
Posted in: Cengage NEET by C.P Singh , Chapter 8 - Work, Energy and Power , Part 1 ,
Tags: A particle of mass m moves on a straight line with its velocity varying with the distance travelled according to the equation v=ax−−√ , where a is a constant. Find the total work done by all the forces during a displacement from x=0→x=d. ,