Answer:
[tex]\vec{C}_1(t)=\displaystyle\left<5\cos(\pi t), 5\sin(\pi t) \right> \text{ for }0\le t\le 1[/tex]
[tex]\vec{C}_2(t)=\displaystyle\left<10t-15, 0 \right> \text{ for }1 < t\le 2[/tex]
Step by step explanation:
To help visualize see the attached graph.
The semicircle can be parametrized by using the standard polar formulas:
[tex]x=r\cos(s), y=r\sin(s), \text{ for }0\le s\le \pi[/tex]
Where r is the radius of the circle, therefore r=5.
Nevertheless, since we want a parameter t starting at 0 and ending at 1, notice we need to adjust the parameter s. So, we need that:
[tex]\text{When }t=0\to s=0\\\text{When }t=1\to s=\pi\\ [/tex]
We can achieve that by setting:
[tex]s=\displaystyle\pi t[/tex]
Therefore, the parametrization of the semicircle becomes:
[tex]\displaystyle x=5\cos(\pi t), y=5\sin(\pi t), \text{ for }0\le t\le 1[/tex]
In vector form:
[tex]\vec{C}_1(t)=\displaystyle \left<5\cos(\pi t), 5\sin(\pi t) \right> \text{ for }0\le t\le 1[/tex]
Then for the segment of line, y remains 0 since we are moving along the x-axis. So, y=0
While x increases from -5 to 5. When t=1, x =-5, and when t=2, x=5. It is like finding the equation of a line with ordered pairs (t, x): (1, -5) and (2, 5). Whose slope is therefore: 10. Then using the point-slope formula:
[tex]x-x_1=m(t-t_1)[/tex]
And plugging the slope and one of the points we get:
[tex]x-5=10(t-2)\to x=10t-15[/tex]
So, now we can build our parametrization for the segment of line:
[tex]\vec{C}_2=\displaystyle\left<10t-15, 0 \right> \text{ for }1 < t\le 2[/tex]
