--- Integral Variable Acceleration Topic Assessment Answers ✦ High Speed
The paper includes a full answer scheme at the end. Time allowed: 45 minutes Total marks: 36
(b) ( s(t) = \int (8t^{3/2} - 54) dt = 8 \cdot \frac{2}{5} t^{5/2} - 54t + D = \frac{16}{5} t^{5/2} - 54t + D ) ( s(4) = \frac{16}{5} \cdot 32 - 216 + D = \frac{512}{5} - 216 + D = 20 ) ( \frac{512}{5} - 216 = \frac{512}{5} - \frac{1080}{5} = -\frac{568}{5} ) So ( -\frac{568}{5} + D = 20 \Rightarrow D = 20 + \frac{568}{5} = \frac{100}{5} + \frac{568}{5} = \frac{668}{5} ) [ s(t) = \frac{16}{5}t^{5/2} - 54t + \frac{668}{5} ] (a) ( v(t) = \int \left(3t - \frac{t^2}{2}\right) dt = \frac{3t^2}{2} - \frac{t^3}{6} + C ) Starts from rest: ( v(0) = 0 \Rightarrow C = 0 ) [ v(t) = \frac{3t^2}{2} - \frac{t^3}{6} ]
(a) Find ( v(t) ) (3 marks) (b) Find ( s(t) ) (2 marks) A car starts from rest with acceleration [ a(t) = 3t - \frac{t^2}{2} ] --- Integral Variable Acceleration Topic Assessment Answers
At ( t = 1 ), ( v = 5 \ \text{m/s} ), ( s = 3 \ \text{m} ).
(c) ( s(3) = 27 - 18 + 15 + 2 = 26 \ \text{m} ) (a) ( v(t) = \int 4(t+1)^{-2} dt = -4(t+1)^{-1} + C ) ( v(0) = -4 + C = 2 \Rightarrow C = 6 ) [ v(t) = 6 - \frac{4}{t+1} ] The paper includes a full answer scheme at the end
(a) Find ( v(t) ) (3 marks) (b) Find ( s(t) ) (2 marks) A particle moves with acceleration [ a = 12\sqrt{t} \quad (t \ge 0) ] Given that ( v = 10 ) when ( t = 4 ) and ( s = 20 ) when ( t = 4 ):
(b) ( s(t) = \int \left(6 - \frac{4}{t+1}\right) dt = 6t - 4\ln(t+1) + D ) ( s(0) = 0 - 0 + D = 0 \Rightarrow D = 0 ) [ s(t) = 6t - 4\ln(t+1) ] (a) ( v(t) = \int 12 t^{1/2} dt = 12 \cdot \frac{2}{3} t^{3/2} + C = 8 t^{3/2} + C ) ( v(4) = 8 \cdot 8 + C = 64 + C = 10 \Rightarrow C = -54 ) [ v(t) = 8t^{3/2} - 54 ] (3 marks) Q1 (a) ( v(t) = \int
(c) Check if ( v(t) = 0 ) in [1,4]: ( v(t) = 4t^3 - 4t^2 + 2t + 3 ) Test ( t=1 ): ( 4 - 4 + 2 + 3 = 5 >0 ) Test ( t=0 ): ( 3 >0 ), cubic positive, likely no root. Check derivative: ( 12t^2-8t+2>0 ) (discriminant 64-96<0) so ( v(t) ) increasing, always positive. No change of direction.
(a) Find ( v(t) ) (3 marks) (b) Find ( s(t) ) (3 marks) (c) Calculate the total distance travelled between ( t = 1 ) and ( t = 4 ) seconds, explaining how you treat any change of direction. (3 marks) Q1 (a) ( v(t) = \int (6t - 4), dt = 3t^2 - 4t + C ) ( v(0) = 5 \Rightarrow C = 5 ) [ v(t) = 3t^2 - 4t + 5 ]
(c) ( s(t) = \int v(t) dt = \frac{t^3}{2} - \frac{t^4}{24} + D ), ( s(0) = 0 \Rightarrow D = 0 ) Distance ( = s(9) = \frac{729}{2} - \frac{6561}{24} ) ( = 364.5 - 273.375 = 91.125 \ \text{m} ) (or ( \frac{729}{8} \ \text{m} )) (a) ( v(t) = \int (2\cos 2t - \sin t) dt = \sin 2t + \cos t + C ) ( v(0) = 0 + 1 + C = 1 \Rightarrow C = 0 ) [ v(t) = \sin 2t + \cos t ]
(b) ( s(t) = \int (\sin 2t + \cos t) dt = -\frac{1}{2}\cos 2t + \sin t + D ) ( s(0) = -\frac12(1) + 0 + D = -\frac12 + D = 0 \Rightarrow D = \frac12 ) [ s(t) = -\frac12\cos 2t + \sin t + \frac12 ] (a) ( v(t) = \int (12t^2 - 8t + 2) dt = 4t^3 - 4t^2 + 2t + C ) ( v(1) = 4 - 4 + 2 + C = 2 + C = 5 \Rightarrow C = 3 ) [ v(t) = 4t^3 - 4t^2 + 2t + 3 ]
