Answer:A)33m
B)32.86m/s
Step-by-step explanation:
Using the equation of motion
V^2=U^2-2aS
Where V=final velocity of the car=0
U=initial velocity=17m/s
a=deceleration=-12m/s^2
S= distance covered by car before stopping
Substituting into the equation
0=17^2-2×12×S
0=289-24S
24S=289
S=289/24
S=12m.
The distance between the car and the deer=45-12=33m
B) Using same equation
Distance,S is now 45m,which is the distance between the car and the deer.while deceleration remains same
V^2=U^2-2aS
0=U^2-2×12×45
U^2=1080
U=√1080
U=32.86m/s
Answer:
A. So therefore distance between deer and car after stopping= 36.5 - 12.04 = 24.46m
B. u = 29.6m/s = initial velocity
Step-by-step explanation:
Given the reaction time as 0.5s
So the distance traveled before applying breaks = u*rt
Where u = initial velocity = 17m/s
rt = reaction time = 0.5s
So distance traveled = 0.5 * 17 = 8.5m
So distance between deer and car before applying breaks = 45 - 8.5 = 36.5m
So therefore using kinematics formula to solve for distance covers after applying breaks
V² = u² + 2as
Where v = final velocity = 0
u = initial velocity = 17m/s
a = deceleration = -12m/s²
s = distance covered
Solving for s = u²/2a
s = 17²/(2*12) = 12.04m
So therefore distance between deer and car after stopping= 36.5 - 12.04 = 24.46m
B. Using the same kinematic formula to derive maximum initial velocity attainable to cover distance of 36.5m before stopping
V² = u² + 2as
V= 0
a = deceleration = -12m/ s
s = distance covered = 36.5m
u = (2as)^½
u = ( 2* 12 * 36.5)^½
u = 29.6m/s
