Solution 9: Graph Transformation

Solution 9

We are given the graph of average velocity $v_{av}$ versus time $t$ and need to derive the graph of instantaneous velocity $v$ versus time $t$.

Key Relationship: Since $v_{av} = \frac{S}{t}$, the displacement is $S(t) = t \cdot v_{av}(t)$. The instantaneous velocity is the derivative $v(t) = \frac{dS}{dt}$.

Interval 1: $0 < t < 1$ s

From the given graph, $v_{av}$ increases linearly from 0 to 2.

Equation: $v_{av} = 2t$.
Displacement: $S = t \cdot (2t) = 2t^2$.
Velocity: $v = \frac{d}{dt}(2t^2) = 4t$.

At $t=1$, $v = 4 \, \text{m/s}$.

Interval 2: $1 < t < 2$ s

From the given graph, $v_{av}$ is constant at 2.

Equation: $v_{av} = 2$.
Displacement: $S = t \cdot 2 = 2t$.
Velocity: $v = \frac{d}{dt}(2t) = 2 \, \text{m/s}$.

The velocity drops instantaneously from 4 to 2 at $t=1$ and remains constant.

Interval 3: $2 < t < 4$ s

From the given graph, $v_{av}$ increases linearly from 2 to 3.

Slope $m = \frac{3-2}{4-2} = 0.5$.
Equation: $v_{av} – 2 = 0.5(t – 2) \implies v_{av} = 0.5t + 1$.
Displacement: $S = t(0.5t + 1) = 0.5t^2 + t$.
Velocity: $v = \frac{d}{dt}(0.5t^2 + t) = t + 1$.

At $t=2$, $v = 2+1 = 3 \, \text{m/s}$. (Jump from 2 to 3)
At $t=4$, $v = 4+1 = 5 \, \text{m/s}$.

Figure 5: The derived instantaneous velocity vs. time graph.