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Page 1 1. (b) When the particle of mass m at O is pushed by y in the direction of A . The spring A will compressed by y while spring B and C will be stretched by ' cos 45 yy = o . So that the total restoring force on the mass m along OA. A B C O m F C F B F A cos 45 cos 45 netABC FFFF =++ oo 2 '45 2 ( cos 45 ) cos 45 2 ky ky ky k y ky =+ =+ = o oo Also ' ' 2 '2 net F ky ky ky k k = Þ = Þ= 22 '2 mm T kk =p =p 2. (b) When mass 700 gm is removed, the left out mass (500 + 400) gm oscillates with a period of 3 sec (500 400 32 t k + \ = =p ......(i) When 500 gm mass is also removed, the left out mass is 400 gm. 400 '2 t k \ =p ...(ii) 3 900 ' 2sec ' 400 t t Þ = Þ= 3. (a) Slope is irrelevant hence 1/2 2 2 æö =p ç÷ èø M T k 4. (a) Tension in the string when bob passes through lowest point 2 = + = +w mv T mg mg mv r () \ =w vr Putting 2 v gh = and 22 2 T pp w = = =p we get ( 2) T m g gh = +p 5. (b) k k Force constant 1 () k Length of spring µ 1 1 1 2 3 3 2 Þ = = Þ= l l k kk k ll 6. (b) Initially time period was 2 l T g =p When train accelerates, the effective value of g becomes 22 () ga + which is greater than g. Hence, new time period, becomes less than the initial time period. a g eff g 7. (b) In accelerated frame of reference, a fictitious force (pseudo force) ma acts on the bob of pendulum as shown in figure. Page 2 1. (b) When the particle of mass m at O is pushed by y in the direction of A . The spring A will compressed by y while spring B and C will be stretched by ' cos 45 yy = o . So that the total restoring force on the mass m along OA. A B C O m F C F B F A cos 45 cos 45 netABC FFFF =++ oo 2 '45 2 ( cos 45 ) cos 45 2 ky ky ky k y ky =+ =+ = o oo Also ' ' 2 '2 net F ky ky ky k k = Þ = Þ= 22 '2 mm T kk =p =p 2. (b) When mass 700 gm is removed, the left out mass (500 + 400) gm oscillates with a period of 3 sec (500 400 32 t k + \ = =p ......(i) When 500 gm mass is also removed, the left out mass is 400 gm. 400 '2 t k \ =p ...(ii) 3 900 ' 2sec ' 400 t t Þ = Þ= 3. (a) Slope is irrelevant hence 1/2 2 2 æö =p ç÷ èø M T k 4. (a) Tension in the string when bob passes through lowest point 2 = + = +w mv T mg mg mv r () \ =w vr Putting 2 v gh = and 22 2 T pp w = = =p we get ( 2) T m g gh = +p 5. (b) k k Force constant 1 () k Length of spring µ 1 1 1 2 3 3 2 Þ = = Þ= l l k kk k ll 6. (b) Initially time period was 2 l T g =p When train accelerates, the effective value of g becomes 22 () ga + which is greater than g. Hence, new time period, becomes less than the initial time period. a g eff g 7. (b) In accelerated frame of reference, a fictitious force (pseudo force) ma acts on the bob of pendulum as shown in figure. DPP/ P 28 79 Hence tan maa mgg q== 1 tan a g - æö Þq= ç÷ èø in the backward direction. 8. (c) 2 l T g =p (Independent of mass) 9. (b) 11 1% 0.5% 22 Tl Tl Tl DD µ Þ = = ´= 10. (c) If suppose bob rises up to a height h as shown then after releasing potential energy at extreme position becomes kinetic energy of mean position h = l (1 – cos ) q l l q 2 max max 1 2 2 mgh mv v gh Þ = Þ= Also, from figure cos lh l - q= (1 cos) hl Þ = -q So, max 2 (1 cos) v gl = -q 11. (a) If initial length 1 100 l = then 2 121 l = By using 11 22 2 Tl l T g Tl =p Þ= Hence, 1 21 2 100 1.1 121 T TT T = Þ= % increase 21 1 100 10% TT T - = ´= 12. (d) After standing centre of mass of the oscillating body will shift upward therefore effective length will decrease and by Tl µ , time period will decrease. 13. (a) No momentum will be transferred because, at extreme position the velocity of bob is zero. 14. (c) The effective acceleration in a lift descending with acceleration 3 g is 2 33 eff gg gg = -= 3 2 22 2/32 eff L LL T g gg æö æ ö æö \ =p =p =p ç÷ ç ÷ ç÷ ç÷ è ø èø èø 15. (c) In series 12 12 eq kk k kk = + so time period 12 12 () 2 mkk T kk + =p 16. (c) Spring constant 1 () Length of the spring ( ) k l µ as length becomes half, k becomes twice i.e. 2k 17. (b) Standard equation for given condition 2 cos 0.16 cos( ) xatxt T p = Þ=-p [As 0.16 a =- meter , 2sec] T = 18. (d) 1 1 2 =p m t k and 2 2 2 =p m t k Equivalent spring constant for shown combination is 12 + kk . So time period t is given by 12 2 =p + m t kk By solving these equations we get 2 22 12 t tt - -- =+ 19. (a) With mass 2 m alone, the extension of the spring l is given as 2 m g kl = ........(i) With mass 12 () mm + , the extension ' l is given by 12 ( ) () m mg kll + = +D .......(ii) The increase in extension is l D which is the amplitude of vibration. Subtracting (i) from (ii), we get 1 mg kl =D or 1 mg l k D= 20. (a) If 11 sin y at =w and 2 sin() at w +p 112 21 121 yya yy aaa Þ + Þ= This is the equation of straight line. Page 3 1. (b) When the particle of mass m at O is pushed by y in the direction of A . The spring A will compressed by y while spring B and C will be stretched by ' cos 45 yy = o . So that the total restoring force on the mass m along OA. A B C O m F C F B F A cos 45 cos 45 netABC FFFF =++ oo 2 '45 2 ( cos 45 ) cos 45 2 ky ky ky k y ky =+ =+ = o oo Also ' ' 2 '2 net F ky ky ky k k = Þ = Þ= 22 '2 mm T kk =p =p 2. (b) When mass 700 gm is removed, the left out mass (500 + 400) gm oscillates with a period of 3 sec (500 400 32 t k + \ = =p ......(i) When 500 gm mass is also removed, the left out mass is 400 gm. 400 '2 t k \ =p ...(ii) 3 900 ' 2sec ' 400 t t Þ = Þ= 3. (a) Slope is irrelevant hence 1/2 2 2 æö =p ç÷ èø M T k 4. (a) Tension in the string when bob passes through lowest point 2 = + = +w mv T mg mg mv r () \ =w vr Putting 2 v gh = and 22 2 T pp w = = =p we get ( 2) T m g gh = +p 5. (b) k k Force constant 1 () k Length of spring µ 1 1 1 2 3 3 2 Þ = = Þ= l l k kk k ll 6. (b) Initially time period was 2 l T g =p When train accelerates, the effective value of g becomes 22 () ga + which is greater than g. Hence, new time period, becomes less than the initial time period. a g eff g 7. (b) In accelerated frame of reference, a fictitious force (pseudo force) ma acts on the bob of pendulum as shown in figure. DPP/ P 28 79 Hence tan maa mgg q== 1 tan a g - æö Þq= ç÷ èø in the backward direction. 8. (c) 2 l T g =p (Independent of mass) 9. (b) 11 1% 0.5% 22 Tl Tl Tl DD µ Þ = = ´= 10. (c) If suppose bob rises up to a height h as shown then after releasing potential energy at extreme position becomes kinetic energy of mean position h = l (1 – cos ) q l l q 2 max max 1 2 2 mgh mv v gh Þ = Þ= Also, from figure cos lh l - q= (1 cos) hl Þ = -q So, max 2 (1 cos) v gl = -q 11. (a) If initial length 1 100 l = then 2 121 l = By using 11 22 2 Tl l T g Tl =p Þ= Hence, 1 21 2 100 1.1 121 T TT T = Þ= % increase 21 1 100 10% TT T - = ´= 12. (d) After standing centre of mass of the oscillating body will shift upward therefore effective length will decrease and by Tl µ , time period will decrease. 13. (a) No momentum will be transferred because, at extreme position the velocity of bob is zero. 14. (c) The effective acceleration in a lift descending with acceleration 3 g is 2 33 eff gg gg = -= 3 2 22 2/32 eff L LL T g gg æö æ ö æö \ =p =p =p ç÷ ç ÷ ç÷ ç÷ è ø èø èø 15. (c) In series 12 12 eq kk k kk = + so time period 12 12 () 2 mkk T kk + =p 16. (c) Spring constant 1 () Length of the spring ( ) k l µ as length becomes half, k becomes twice i.e. 2k 17. (b) Standard equation for given condition 2 cos 0.16 cos( ) xatxt T p = Þ=-p [As 0.16 a =- meter , 2sec] T = 18. (d) 1 1 2 =p m t k and 2 2 2 =p m t k Equivalent spring constant for shown combination is 12 + kk . So time period t is given by 12 2 =p + m t kk By solving these equations we get 2 22 12 t tt - -- =+ 19. (a) With mass 2 m alone, the extension of the spring l is given as 2 m g kl = ........(i) With mass 12 () mm + , the extension ' l is given by 12 ( ) () m mg kll + = +D .......(ii) The increase in extension is l D which is the amplitude of vibration. Subtracting (i) from (ii), we get 1 mg kl =D or 1 mg l k D= 20. (a) If 11 sin y at =w and 2 sin() at w +p 112 21 121 yya yy aaa Þ + Þ= This is the equation of straight line. 80 DPP/ P 28 21. (c) Energy of particle is maximum at resonant frequency i.e., 20 w =w . For amplitude resonance (amplitude maximum) frequency of driver force w = 2 22 0 10 2 bm w - Þ w ¹w 22. (b) c A ; when b 0, a c, amplitude a bc = == +- A. ®¥ This corresponds to resonance. 23. (b) Let the velocity acquired by A and B be V , then v mv mV mV V 2 = + Þ= Also 2 2 22 1 1 11 mv mV mV kx 2 2 22 = ++ Where x is the maximum compression of the spring. On solving the above equations, we get 1/2 m xv 2k æö = ç÷ èø At maximum compression, kinetic energy of the A – B system 2 2 22 1 1 mv mV mV mV 224 = + == 24. (d) L L mg cos q mg sin q mg q – f + f From following figure it is clear that T Mg cos? Centripetal force -= 2 Mv T Mgcos? L Þ-= Also tangential acceleration T a g sin?. = 25. (a) Except (4) all statements are wrong. 26. (b) 27. (b). For minimum time period w 2 A = mg 2 2 4 A mg T p = , T = 0.2 sec, At t = 0.05 sec. y = A sin wt = 1 sn 2 0.2 p × 0.05cm. = 1cm. PE = mgy = 1 × 10 × 1 100 = 0.1 Joule 28. (c) Statement -1 is False, Statement-2 is True. 29. (a) The time period of a oscillating spring is given by , 1 2 m TT k k = p Þµ Since the spring constant is large for hard spring, therefore hard spring has a less periodic time as compared to soft spring. 30. (d) Time period of simple pendulum of length l is, 2 l T Tl g = p Þµ 1 2 Tl Tl DD Þ= \ 1 3 1.5% 2 D = ´= T TRead More
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