(a) Let's convert the final speed of the car in m/s:
[tex]v_f = 61 km/h = 16.9 m/s[/tex]
The kinetic energy of the car at t=19 s is
[tex]K= \frac{1}{2}mv_f^2= \frac{1}{2}(1400 kg)(16.9 m/s)^2=2.00 \cdot 10^5 J [/tex]
(b) The average power delivered by the engine of the car during the 19 s is equal to the work done by the engine divided by the time interval:
[tex]P= \frac{W}{\Delta t} [/tex]
But the work done is equal to the increase in kinetic energy of the car, and since its initial kinetic energy is zero (because the car starts from rest), this translates into
[tex]P= \frac{K}{\Delta t}= \frac{2.00 \cdot 10^5 J}{19 s}=1.05 \cdot 10^4 W [/tex]
(c) The instantaneous power is given by
[tex]P_i = Fv_f[/tex]
where F is the force exerted by the engine, equal to F=ma.
So we need to find the acceleration first:
[tex]a= \frac{v_f-v_i}{\Delta t}= \frac{16.9 m/s}{19 s}=0.89 m/s^2 [/tex]
And the problem says this acceleration is constant during the motion, so now we can calculate the instantaneous power at t=19 s:
[tex]P_i = Fv=(ma)v=(1400 kg)(0.89 m/s^2)(16.9 m/s)=2.11 \cdot 10^4 W[/tex]
