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Page 1 1. (c) If a stone is dropped from height h then 2 1 2 h gt = ......... (i) If a stone is thrown upward with velocity u then h = 2 11 1 2 ut gt -+ ......... (ii) If a stone is thrown downward with velocity u then 2 22 1 2 h ut gt =+ ......... (iii) From (i), (ii) and (iii) we get 22 11 11 22 ut gt gt - += ......... (iv) 22 22 11 22 ut gt gt += ......... (v) Dividing (iv) and (v) we get 22 1 1 22 2 2 1 () 2 1 () 2 gtt ut ut gtt - - \= - or 22 11 22 2 2 t tt t tt - -= - By solving 12 t tt = 2. (c) Since direction of v is opposite to the direction of g and h so from equation of motion 2 1 2 =-n+ h t gt Þ 2 2 20 -n-= gt th Þ 2 2 48 2 n± n+ = gh t g Þ 2 2 11 éù n = ++ êú n ëû gh t g 3. (c) 22 1 11 11 1 0 2/ 22 h ut gt t gt t g = + Þ = ´ + Þ= V elocity after travelling 1m distance 2 2 22 2 (0)212 = + Þ n = + ´ Þ n= vugh gg For second 1 meter distance 22 2 2 22 1 1 2 2 2 20 2 g t gt gt gt = ´ + Þ + -= 2 22 88 22 2 g gg t g g - ±+ -± == Taking + ve sign 2 (2 2)/ tg =- 1 2 2/ 1 (2 2)/ 21 g t t g \== -- and so on. 4. (d) Interval of ball throw = 2 sec. If we want that minimum three (more than two) ball remain in air then time of flight of first ball must be greater than 4 sec. T > 4 sec. 2 4sec 19.6/ u u ms g > Þ> for u = 19.6 First ball will just strike the ground(in sky) Second ball will be at highest point (in sky) Third ball will be at point of projection or at ground (not in sky) 5. (a) The distance covered by the ball during the last t seconds of its upward motion = Distance covered by it in first t seconds of its downward motion From 2 1 2 h ut gt =+ 2 1 2 h gt = [As u = 0 for it downward motion] 6. (d) In the positive region the velocity decreases linearly (during rise) and in the negative region velocity increases linearly (during fall) and the direction is opposite to each other during rise and fall, hence fall is shown in the negative region. 7. (a) For the given condition initial height h = d and velocity of the ball is zero. When the ball moves downward its velocity increases and it will be maximum when the ball hits the ground & just after the collision it becomes half and in opposite direction. As the ball moves upward its velocity again decreases and becomes zero at height d/2. This explanation match with graph (a). 8. (c) Acceleration of body along AB is g cos q Distance travelled in time 2 1 sec ( cos ) 2 t AB gt = =q From DABC, AB = 2R cosq; 2 1 2 cos cos 2 R gt q=q 2 2 4 or == RR tt gg 9. (b) It has lesser initial upward velocity . 10. (b) At maximum height velocity n = 0 Page 2 1. (c) If a stone is dropped from height h then 2 1 2 h gt = ......... (i) If a stone is thrown upward with velocity u then h = 2 11 1 2 ut gt -+ ......... (ii) If a stone is thrown downward with velocity u then 2 22 1 2 h ut gt =+ ......... (iii) From (i), (ii) and (iii) we get 22 11 11 22 ut gt gt - += ......... (iv) 22 22 11 22 ut gt gt += ......... (v) Dividing (iv) and (v) we get 22 1 1 22 2 2 1 () 2 1 () 2 gtt ut ut gtt - - \= - or 22 11 22 2 2 t tt t tt - -= - By solving 12 t tt = 2. (c) Since direction of v is opposite to the direction of g and h so from equation of motion 2 1 2 =-n+ h t gt Þ 2 2 20 -n-= gt th Þ 2 2 48 2 n± n+ = gh t g Þ 2 2 11 éù n = ++ êú n ëû gh t g 3. (c) 22 1 11 11 1 0 2/ 22 h ut gt t gt t g = + Þ = ´ + Þ= V elocity after travelling 1m distance 2 2 22 2 (0)212 = + Þ n = + ´ Þ n= vugh gg For second 1 meter distance 22 2 2 22 1 1 2 2 2 20 2 g t gt gt gt = ´ + Þ + -= 2 22 88 22 2 g gg t g g - ±+ -± == Taking + ve sign 2 (2 2)/ tg =- 1 2 2/ 1 (2 2)/ 21 g t t g \== -- and so on. 4. (d) Interval of ball throw = 2 sec. If we want that minimum three (more than two) ball remain in air then time of flight of first ball must be greater than 4 sec. T > 4 sec. 2 4sec 19.6/ u u ms g > Þ> for u = 19.6 First ball will just strike the ground(in sky) Second ball will be at highest point (in sky) Third ball will be at point of projection or at ground (not in sky) 5. (a) The distance covered by the ball during the last t seconds of its upward motion = Distance covered by it in first t seconds of its downward motion From 2 1 2 h ut gt =+ 2 1 2 h gt = [As u = 0 for it downward motion] 6. (d) In the positive region the velocity decreases linearly (during rise) and in the negative region velocity increases linearly (during fall) and the direction is opposite to each other during rise and fall, hence fall is shown in the negative region. 7. (a) For the given condition initial height h = d and velocity of the ball is zero. When the ball moves downward its velocity increases and it will be maximum when the ball hits the ground & just after the collision it becomes half and in opposite direction. As the ball moves upward its velocity again decreases and becomes zero at height d/2. This explanation match with graph (a). 8. (c) Acceleration of body along AB is g cos q Distance travelled in time 2 1 sec ( cos ) 2 t AB gt = =q From DABC, AB = 2R cosq; 2 1 2 cos cos 2 R gt q=q 2 2 4 or == RR tt gg 9. (b) It has lesser initial upward velocity . 10. (b) At maximum height velocity n = 0 DPP/ P 04 9 We know that n = u + at, hence 0 u gT u gT = - Þ= When , 2 n= u then 2 2 22 u u gTT u gt gt gt t = - Þ = Þ = Þ= Hence at , 2 T t = it acquires velocity 2 u . 11. (b) 11 22 2 th h t g th = Þ= 12. (c) Speed of the object at reaching the ground 2 n= gh If heights are equal then velocity will also be equal. 13. (b) 3 10 10 (2 3 1) 35 2 rd Sm = + ´ -= 3 2 2 107 10 (2 2 1) 25 25 rd nd nd S S S = + ´-= Þ= 14. (c) (2 1) n Sn µ- . In equal time interval of 2 seconds Ratio of distance = 1 : 3 : 5 15. (c) Net acceleration of a body when thrown upward = acceleration of body – acceleration due to gravity = a – g 16. (d) The initial velocity of aeroplane is horizontal, then the vertical component of velocity of packet will be zero. So 2h t g = 17. (b) Time = Totallength 50 50 100 4sec Relative velocity 10 15 25 + = == + 18. (d) Relative velocity = 10 + 5 = 15 m/sec 150 10 sec 15 \== t 19. (a) When two particles moves towards each other then v 1 + v 2 = 4 ....... (i) When these particles moves in the same direction then v 1 – v 2 = 4 ....... (ii) By solving v 1 = 5 and v 2 = 1 m/s 20. (b) n = n -n uuu r uu r u u r ct ct () n = n + -n uuu r uu r uu r ct ct 45° ct v c v t v - t v Velocity of car w.r.t. train () n uuur ct is towards West – North 21. (a) As the trains are moving in the same direction. So the initial relative speed (v 1 – v 2 ) and by applying retardation final relative speed becomes zero. From 12 12 0() - = - Þ = - - Þ= vv v u at v v at t a 22. (d) Let A v r and B v r be the respective velocities of the particles at A and B. The relative velocity of particle at A. w.r.t. to that at B is given by ) v ( v v v B A B A r r r r - + = - 300m A B v =25m/s A (see figure). From triangle law of velocities if OP and PQ represent A v r and B v r - , then the required relative velocity R v r is given by OQ . 22 R | v | 25 20 625 400 32.02 m / s = + = += r If , PQO q = Ð then 1 255 tan tan 204 - æö q= Þ q= ç÷ èø O Q P 25 20 v A v =20m/s B Thus, the particle at A, appears to approach B, in a direction making an angle of tan –1 (5/4) with its direction of motion. Let us draw a line from A, as AC, such that BCA Ð is equal to q . A C B M 300m Thus, to B, A appears to move along AC. From B, draw a perpendicular to AC as BM. BM is the shortest distance between them. \ 4 BM ABcos 300 187.41 m 41 = q= ´= Also, m 26 . 234 sin AB AM = q = \ time taken to cover a distance Page 3 1. (c) If a stone is dropped from height h then 2 1 2 h gt = ......... (i) If a stone is thrown upward with velocity u then h = 2 11 1 2 ut gt -+ ......... (ii) If a stone is thrown downward with velocity u then 2 22 1 2 h ut gt =+ ......... (iii) From (i), (ii) and (iii) we get 22 11 11 22 ut gt gt - += ......... (iv) 22 22 11 22 ut gt gt += ......... (v) Dividing (iv) and (v) we get 22 1 1 22 2 2 1 () 2 1 () 2 gtt ut ut gtt - - \= - or 22 11 22 2 2 t tt t tt - -= - By solving 12 t tt = 2. (c) Since direction of v is opposite to the direction of g and h so from equation of motion 2 1 2 =-n+ h t gt Þ 2 2 20 -n-= gt th Þ 2 2 48 2 n± n+ = gh t g Þ 2 2 11 éù n = ++ êú n ëû gh t g 3. (c) 22 1 11 11 1 0 2/ 22 h ut gt t gt t g = + Þ = ´ + Þ= V elocity after travelling 1m distance 2 2 22 2 (0)212 = + Þ n = + ´ Þ n= vugh gg For second 1 meter distance 22 2 2 22 1 1 2 2 2 20 2 g t gt gt gt = ´ + Þ + -= 2 22 88 22 2 g gg t g g - ±+ -± == Taking + ve sign 2 (2 2)/ tg =- 1 2 2/ 1 (2 2)/ 21 g t t g \== -- and so on. 4. (d) Interval of ball throw = 2 sec. If we want that minimum three (more than two) ball remain in air then time of flight of first ball must be greater than 4 sec. T > 4 sec. 2 4sec 19.6/ u u ms g > Þ> for u = 19.6 First ball will just strike the ground(in sky) Second ball will be at highest point (in sky) Third ball will be at point of projection or at ground (not in sky) 5. (a) The distance covered by the ball during the last t seconds of its upward motion = Distance covered by it in first t seconds of its downward motion From 2 1 2 h ut gt =+ 2 1 2 h gt = [As u = 0 for it downward motion] 6. (d) In the positive region the velocity decreases linearly (during rise) and in the negative region velocity increases linearly (during fall) and the direction is opposite to each other during rise and fall, hence fall is shown in the negative region. 7. (a) For the given condition initial height h = d and velocity of the ball is zero. When the ball moves downward its velocity increases and it will be maximum when the ball hits the ground & just after the collision it becomes half and in opposite direction. As the ball moves upward its velocity again decreases and becomes zero at height d/2. This explanation match with graph (a). 8. (c) Acceleration of body along AB is g cos q Distance travelled in time 2 1 sec ( cos ) 2 t AB gt = =q From DABC, AB = 2R cosq; 2 1 2 cos cos 2 R gt q=q 2 2 4 or == RR tt gg 9. (b) It has lesser initial upward velocity . 10. (b) At maximum height velocity n = 0 DPP/ P 04 9 We know that n = u + at, hence 0 u gT u gT = - Þ= When , 2 n= u then 2 2 22 u u gTT u gt gt gt t = - Þ = Þ = Þ= Hence at , 2 T t = it acquires velocity 2 u . 11. (b) 11 22 2 th h t g th = Þ= 12. (c) Speed of the object at reaching the ground 2 n= gh If heights are equal then velocity will also be equal. 13. (b) 3 10 10 (2 3 1) 35 2 rd Sm = + ´ -= 3 2 2 107 10 (2 2 1) 25 25 rd nd nd S S S = + ´-= Þ= 14. (c) (2 1) n Sn µ- . In equal time interval of 2 seconds Ratio of distance = 1 : 3 : 5 15. (c) Net acceleration of a body when thrown upward = acceleration of body – acceleration due to gravity = a – g 16. (d) The initial velocity of aeroplane is horizontal, then the vertical component of velocity of packet will be zero. So 2h t g = 17. (b) Time = Totallength 50 50 100 4sec Relative velocity 10 15 25 + = == + 18. (d) Relative velocity = 10 + 5 = 15 m/sec 150 10 sec 15 \== t 19. (a) When two particles moves towards each other then v 1 + v 2 = 4 ....... (i) When these particles moves in the same direction then v 1 – v 2 = 4 ....... (ii) By solving v 1 = 5 and v 2 = 1 m/s 20. (b) n = n -n uuu r uu r u u r ct ct () n = n + -n uuu r uu r uu r ct ct 45° ct v c v t v - t v Velocity of car w.r.t. train () n uuur ct is towards West – North 21. (a) As the trains are moving in the same direction. So the initial relative speed (v 1 – v 2 ) and by applying retardation final relative speed becomes zero. From 12 12 0() - = - Þ = - - Þ= vv v u at v v at t a 22. (d) Let A v r and B v r be the respective velocities of the particles at A and B. The relative velocity of particle at A. w.r.t. to that at B is given by ) v ( v v v B A B A r r r r - + = - 300m A B v =25m/s A (see figure). From triangle law of velocities if OP and PQ represent A v r and B v r - , then the required relative velocity R v r is given by OQ . 22 R | v | 25 20 625 400 32.02 m / s = + = += r If , PQO q = Ð then 1 255 tan tan 204 - æö q= Þ q= ç÷ èø O Q P 25 20 v A v =20m/s B Thus, the particle at A, appears to approach B, in a direction making an angle of tan –1 (5/4) with its direction of motion. Let us draw a line from A, as AC, such that BCA Ð is equal to q . A C B M 300m Thus, to B, A appears to move along AC. From B, draw a perpendicular to AC as BM. BM is the shortest distance between them. \ 4 BM ABcos 300 187.41 m 41 = q= ´= Also, m 26 . 234 sin AB AM = q = \ time taken to cover a distance 10 DPP/ P 04 AB = 234.26 m with a velocity of 32.02 m/s = 234.26 7.32 sec. 32.02 = 23. (d) Since the wind is blowing toward the east, the plane must head west of north as shown in figure. The velocity of the plane relative to the ground r v pg will be the sum of the velocity of the plane relative to the air r v pa and the velocity of the air relative to the ground r v ag . (i) 1. The velocity of the plane relative to the ground is given by equation : r v pg = r v pa + r v ag 2. The sine of the angle q between the velocity of the plane and north equals the ratio of v ag and v pa . sin q = v v ag pa = 90 km/h 200 km / h = 0.45 \ q = 26.74 (ii) Since v ag and v pg are perpendicular, we can use the Pythagorean theorem to find the magnitude of r v pg . v 2 pg = v 2 ag + v 2 pg v pg = v v pa ag 2 2 - = ( /)( /) 200 90 2 2 kmh kmh - = 179 km/h. 24. (a) Using, 2 1 S uT aT 2 =+ r r r (i) 2 1 40 10T gT 2 - =- or 2 40 10T 5T - =- or 2 5T 10T 40 0 - -= h v u u=10m/s 40m or 2 10 10 4 5( 40) 10 100 800 T 2 5 10 + - ´- ++ == ´ 10 30 4 sec. 10 + == (ii) 2 10 t 2 sec. g ´ == (iii) v = 10 + g × 2 = 30 m/s 25. (b) V plane = 100 m/s v plane v total v wind 22 total V (20) (100) 2 20 100 cos135 = + +´´ ´° = 1 400 10000 2 20 100 2 æö + + ´ ´ ´- ç÷ èø = 87 m/s 26. (c) wind plane v tan v f= = 20 100 v plane v total v wind f 1 20 tan 100 - æö \ f= ç÷ èø 27. (d) plane total v cos v f= plane total v 100 v m/s cos cos \ == ff 28. (a) If components of velocities of boat relative to river is same normal to river flow (as shown in figure) are same, both boats reach other bank simultaneously. v v q q Boat 1 Boat 2 River 29. (a) Both statement - 1 & statement - 2 are correct and statement - 2 is correct explanation of statement - 2 30. (d) Statement - 1 is true but statement - 2 is false.Read More
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