Answer:
It results -14 in either way
Step-by-step explanation:
Velocity As A Rate Of Change
The velocity of an object can be computed as the rate of change of its displacement (or position taken as a vector) over time. If we compute it as a derivative, it's called instantaneous velocity, and if computed as the slope of the function (difference quotient) at a certain point it's the average velocity
The position of the object as a function of time is
[tex]\displaystyle s(t)=6-14t[/tex]
Computing the derivative
[tex]\displaystyle s'(t)=-14[/tex]
We can see it's a constant value. If we use the slope or rate of change:
[tex]\displaystyle v=\frac{s_2-s_1}{t_2-t_1}[/tex]
Now let's fix two values for time
[tex]\displaystyle t_1=5\ sec,\ t_2=8\ sec[/tex]
and compute the corresponding positions, by using the given function
[tex]\displaystyle s_1=6-14(5)=-64[/tex]
[tex]\displaystyle s_2=6-14(8)=-106[/tex]
Now we compute the average velocity
[tex]\displaystyle v=\frac{-106-(-64)}{8-5}[/tex]
[tex]\displaystyle v=\frac{-106+64}{3}=\frac{-42}{3}[/tex]
[tex]\displaystyle v=-14[/tex]
We get the very same result in both ways to compute v. It happens because the position is related with time as a linear function, it's called a constant velocity motion.
