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X2 t06 04 uniform circular motion (2012)

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Nigel Simmons
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Acceleration with Uniform Circular Motion
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant 
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A r O
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r O  P
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r O  The acceleration of the particle is the change in velocity with respect to time. P
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v v’
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v v’ v
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A A particle moves from A to P with constant angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v’  v v
Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A A particle moves from A to P with constant angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’  v v’ This triangle of vectors is similar to OAP v
A v’  v r O  v r
A v’  v r O  v r P v v  AP r
A v’  v r O  v r P v v  AP r v  AP v  r
A v’  v r O  v r P v v  AP r v  AP v  r v a t
A v’  v r O  v r P v v  AP r v  AP v  r v a t v  AP a r  t
A v’  v r O  v r P v v  AP r v  AP v  r v a t v  AP a r  t But, as Δt  0, AP  arcAP
A v’  v r O  v r P v v  AP r v  AP v  r v a t v  AP a r  t But, as Δt  0, AP  arcAP v  arcAP  a  lim t 0 r  t
A v’  v r distance  speed  time O  arcAP  v  t v r P v v  AP r v  AP v  r v a t v  AP a r  t But, as Δt  0, AP  arcAP v  arcAP  a  lim t 0 r  t
A v’  v r distance  speed  time O  arcAP  v  t v r P v v  v  v  t AP r  a  lim t 0 r  t v  AP v  r v2  lim v t 0 r a t v2  v  AP r a r  t But, as Δt  0, AP  arcAP v  arcAP  a  lim t 0 r  t
A v’  v r distance  speed  time O  arcAP  v  t v r P v v  v  v  t AP r  a  lim t 0 r  t v  AP v  r v2  lim v t 0 r a t v2  v  AP r a r  t  the acceleration in uniform circular But, as Δt  0, AP  arcAP v2 v  arcAP motion has magnitude and is  a  lim r t 0 r  t directed towards the centre
Acceleration Involved in Uniform Circular Motion v2 a r
Acceleration Involved in Uniform Circular Motion v2 a r OR a  r 2
Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 a r OR a  r 2
Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR a  r 2
Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR OR a  r 2 F  mr 2
Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR OR a  r 2 F  mr 2 e.g. (i) (2003) A particle P of mass m moves with constant angular velocity  on a circle of radius r. Its position at time t is given by; x  r cos y  r sin  , where   t
Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR OR a  r 2 F  mr 2 e.g. (i) (2003) A particle P of mass m moves with constant angular velocity  on a circle of radius r. Its position at time t is given by; x  r cos y  r sin  , where   t a) Show that there is an inward radial force of magnitude mr 2 acting on P.
y P r y  r sin   x  r cos x
x  r cos y P r y  r sin   x  r cos x
x  r cos y y  r sin  P r y  r sin   x  r cos x
x  r cos y y  r sin  d x   r sin    P dt r y  r sin    r sin   x  r cos x
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos  x  r cos x
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos  d x  r cos x    r cos  x dt   r 2 cos   2 x
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x2   2 y
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2   2 y y  x 
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2   2 y a y   x 
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x 2 y 2   2 y a y   x 
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x 2 y 2   2 y   4 x2   4 y2   4 x 2  y 2  a y    4r 2  x 
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x y 2 2   2 y   4 x2   4 y2   4 x 2  y 2  a y    4r 2 a  r 2  x 
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x y 2 2   2 y   4 x2   4 y2   4 x 2  y 2  a y    4r 2 a  r 2  x  F  ma  F  mr 2
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin  y    x 2 a      2 x y 2 2   tan 1   2 y x    4 x2   4 y2   4 x 2  y 2  a y    4r 2 a  r 2  x  F  ma  F  mr 2
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin  y    x 2 a      2 x y 2 2   tan 1   2 y x    4 x2   4 y2   2 y   tan 1     4 x 2  y 2    x  2 a y    4r 2 y  tan 1 a  r 2 x  F  ma  x   F  mr 2
x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin  y    x 2 a      2 x y 2 2   tan 1   2 y x    4 x2   4 y2   2 y   tan 1     4 x 2  y 2    x  2 a y    4r 2 y  tan 1 a  r 2 x  F  ma  x   F  mr 2  There is a force , F  mr 2 , acting towards the centre
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 m  mr 2 x
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am m  mr 2 x r2
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am mr 2  Am r2 m  mr 2 x r2
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am mr 2  Am r2 m  mr 2 x r2 Am r3  m 2 A  2 
b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am mr 2  Am r2 m  mr 2 x r2 Am r3  m 2 A  2  A r3 2
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string.
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string.
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. T m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T 0  mg  T m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 T 0  mg  T T  40 9.8  392 N m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 0  mg  T T 392  2 0.5 2 T  40 9.8  392 N m x mg
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 0  mg  T T 392  2 0.5 2 T  40 9.8  2  392  392 N mg   392 m x   2 98rad/s
(ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 0  mg  T T 392  2 0.5 2 T  40 9.8  2  392  392 N mg   392 m x   2 98rad/s Exercise 9B; all

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  • 1. Acceleration with Uniform Circular Motion
  • 2. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.
  • 3. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant 
  • 4. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A r O
  • 5. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r O  P
  • 6. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r O  The acceleration of the particle is the change in velocity with respect to time. P
  • 7. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P
  • 8. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’
  • 9. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v
  • 10. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v v’
  • 11. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A particle moves from A to P with constant A angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v v’ v
  • 12. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A A particle moves from A to P with constant angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’ v’  v v
  • 13. Acceleration with Uniform Circular Motion Uniform circular motion is when a particle moves with constant angular velocity.  the magnitude of the linear velocity will also be constant  A A particle moves from A to P with constant angular velocity. r v O  The acceleration of the particle is the change in velocity with respect to time. P v’  v v’ This triangle of vectors is similar to OAP v
  • 14. A v’  v r O  v r
  • 15. A v’  v r O  v r P v v  AP r
  • 16. A v’  v r O  v r P v v  AP r v  AP v  r
  • 17. A v’  v r O  v r P v v  AP r v  AP v  r v a t
  • 18. A v’  v r O  v r P v v  AP r v  AP v  r v a t v  AP a r  t
  • 19. A v’  v r O  v r P v v  AP r v  AP v  r v a t v  AP a r  t But, as Δt  0, AP  arcAP
  • 20. A v’  v r O  v r P v v  AP r v  AP v  r v a t v  AP a r  t But, as Δt  0, AP  arcAP v  arcAP  a  lim t 0 r  t
  • 21. A v’  v r distance  speed  time O  arcAP  v  t v r P v v  AP r v  AP v  r v a t v  AP a r  t But, as Δt  0, AP  arcAP v  arcAP  a  lim t 0 r  t
  • 22. A v’  v r distance  speed  time O  arcAP  v  t v r P v v  v  v  t AP r  a  lim t 0 r  t v  AP v  r v2  lim v t 0 r a t v2  v  AP r a r  t But, as Δt  0, AP  arcAP v  arcAP  a  lim t 0 r  t
  • 23. A v’  v r distance  speed  time O  arcAP  v  t v r P v v  v  v  t AP r  a  lim t 0 r  t v  AP v  r v2  lim v t 0 r a t v2  v  AP r a r  t  the acceleration in uniform circular But, as Δt  0, AP  arcAP v2 v  arcAP motion has magnitude and is  a  lim r t 0 r  t directed towards the centre
  • 24. Acceleration Involved in Uniform Circular Motion v2 a r
  • 25. Acceleration Involved in Uniform Circular Motion v2 a r OR a  r 2
  • 26. Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 a r OR a  r 2
  • 27. Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR a  r 2
  • 28. Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR OR a  r 2 F  mr 2
  • 29. Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR OR a  r 2 F  mr 2 e.g. (i) (2003) A particle P of mass m moves with constant angular velocity  on a circle of radius r. Its position at time t is given by; x  r cos y  r sin  , where   t
  • 30. Acceleration Involved in Forces Involved in Uniform Circular Motion Uniform Circular Motion v2 mv 2 a F r r OR OR a  r 2 F  mr 2 e.g. (i) (2003) A particle P of mass m moves with constant angular velocity  on a circle of radius r. Its position at time t is given by; x  r cos y  r sin  , where   t a) Show that there is an inward radial force of magnitude mr 2 acting on P.
  • 31. y P r y  r sin   x  r cos x
  • 32. x  r cos y P r y  r sin   x  r cos x
  • 33. x  r cos y y  r sin  P r y  r sin   x  r cos x
  • 34. x  r cos y y  r sin  d x   r sin    P dt r y  r sin    r sin   x  r cos x
  • 35. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos  x  r cos x
  • 36. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos  d x  r cos x    r cos  x dt   r 2 cos   2 x
  • 37. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x2   2 y
  • 38. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2   2 y y  x 
  • 39. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2   2 y a y   x 
  • 40. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x 2 y 2   2 y a y   x 
  • 41. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x 2 y 2   2 y   4 x2   4 y2   4 x 2  y 2  a y    4r 2  x 
  • 42. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x y 2 2   2 y   4 x2   4 y2   4 x 2  y 2  a y    4r 2 a  r 2  x 
  • 43. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin    x 2 a      2 x y 2 2   2 y   4 x2   4 y2   4 x 2  y 2  a y    4r 2 a  r 2  x  F  ma  F  mr 2
  • 44. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin  y    x 2 a      2 x y 2 2   tan 1   2 y x    4 x2   4 y2   4 x 2  y 2  a y    4r 2 a  r 2  x  F  ma  F  mr 2
  • 45. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin  y    x 2 a      2 x y 2 2   tan 1   2 y x    4 x2   4 y2   2 y   tan 1     4 x 2  y 2    x  2 a y    4r 2 y  tan 1 a  r 2 x  F  ma  x   F  mr 2
  • 46. x  r cos y y  r sin  d d x   r sin    P y  r cos   dt dt r y  r sin    r sin   r cos     r cos  x d x  r cos x    r sin   d y dt dt   r 2 cos   r 2 sin  y    x 2 a      2 x y 2 2   tan 1   2 y x    4 x2   4 y2   2 y   tan 1     4 x 2  y 2    x  2 a y    4r 2 y  tan 1 a  r 2 x  F  ma  x   F  mr 2  There is a force , F  mr 2 , acting towards the centre
  • 47. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2
  • 48. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2
  • 49. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 m  mr 2 x
  • 50. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am m  mr 2 x r2
  • 51. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am mr 2  Am r2 m  mr 2 x r2
  • 52. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am mr 2  Am r2 m  mr 2 x r2 Am r3  m 2 A  2 
  • 53. b) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity  at a distance r from the centre of the Earth. The gravitational force exerted by Earth on the satellite is Am where r2 A is a constant. By considering all other forces on the satellite to be negligible, show that; A r 3  2 Am mr 2  Am r2 m  mr 2 x r2 Am r3  m 2 A  2  A r3 2
  • 54. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string.
  • 55. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string.
  • 56. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x
  • 57. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x mg
  • 58. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. T m x mg
  • 59. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T m x mg
  • 60. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T 0  mg  T m x mg
  • 61. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
  • 62. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
  • 63. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
  • 64. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T 0  mg  T T  40 9.8  392 N m x mg
  • 65. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 T 0  mg  T T  40 9.8  392 N m x mg
  • 66. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 0  mg  T T 392  2 0.5 2 T  40 9.8  392 N m x mg
  • 67. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 0  mg  T T 392  2 0.5 2 T  40 9.8  2  392  392 N mg   392 m x   2 98rad/s
  • 68. (ii) A string is 50cm long and it will break if a ,mass exceeding 40kg is hung from it. A mass of 2kg is attached to one end of the string and it is revolved in a circle. Find the greatest angular velocity which may be imparted without breaking the string. m x T m  mg  T x T  mr 2 0  mg  T T 392  2 0.5 2 T  40 9.8  2  392  392 N mg   392 m x   2 98rad/s Exercise 9B; all