Answered

IDNLearn.com: Your reliable source for finding precise answers. Find in-depth and accurate answers to all your questions from our knowledgeable and dedicated community members.

The proof that the point [tex]\((1, \sqrt{3})\)[/tex] lies on the circle centered at the origin and containing the point [tex]\((0,2)\)[/tex] is found in the table below. What is the justification for the 4th statement?

\begin{tabular}{|c|c|}
\hline
Statement & Justification \\
\hline
\begin{tabular}{l}
A circle is centered at [tex]\((0,0)\)[/tex] and \\
contains the point [tex]\((0,2)\)[/tex].
\end{tabular} & Given \\
\hline
\begin{tabular}{l}
The radius of the circle is the distance \\
from [tex]\((0,0)\)[/tex] to [tex]\((0,2)\)[/tex].
\end{tabular} & Definition of radius \\
\hline
\begin{tabular}{l}
The distance from [tex]\((0,0)\)[/tex] to [tex]\((0,2)\)[/tex] is \\
[tex]\(\sqrt{(0-0)^2+(2-0)^2}=\sqrt{2^2}=2\)[/tex]
\end{tabular} & Distance formula \\
\hline
\begin{tabular}{l}
If [tex]\((1, \sqrt{3})\)[/tex] lies on the circle, it must be the same distance from the center as [tex]\((0,2)\)[/tex]. \\
The distance from [tex]\((0,0)\)[/tex] to [tex]\((1, \sqrt{3})\)[/tex] is \\
[tex]\(\sqrt{(0-1)^2+(0-\sqrt{3})^2}=\sqrt{1+3}=2\)[/tex]
\end{tabular} & Distance formula \\
\hline
\end{tabular}

Since [tex]\((1, \sqrt{3})\)[/tex] is 2 units from [tex]\((0,0)\)[/tex], it lies on a circle that is centered at the origin and contains the point [tex]\((0,2)\)[/tex].

Sagot :

GinnyAnsweridn
To provide a detailed, step-by-step solution for this proof, we need to establish that the point [tex]\((1, \sqrt{3})\)[/tex] lies on the circle centered at the origin and containing the point [tex]\((0,2)\)[/tex]. Here is the justification for each statement leading up to the conclusion:

1. Statement: A circle is centered at [tex]\((0,0)\)[/tex] and contains the point [tex]\((0,2)\)[/tex].
- Justification: Given.

2. Statement: The radius of the circle is the distance from [tex]\((0,0)\)[/tex] to [tex]\((0,2)\)[/tex].
- Justification: Definition of radius.

3. Statement: The distance from [tex]\((0,0)\)[/tex] to [tex]\((0,2)\)[/tex] is [tex]\(\sqrt{(0-0)^2 + (2-0)^2} = \sqrt{2^2} = 2\)[/tex].
- Justification: Distance formula.

Having established the radius of the circle, we move on to verify whether the point [tex]\((1, \sqrt{3})\)[/tex] lies on the same circle. We do this by calculating its distance to the center [tex]\((0,0)\)[/tex] and checking if it equals the radius of the circle.

4. Statement: If [tex]\((1, \sqrt{3})\)[/tex] lies on the circle, it must be the same distance from the center [tex]\((0,0)\)[/tex] as [tex]\((0,2)\)[/tex].
- Justification: Points on a circle are equidistant from the center by definition.

Next, we calculate the distance from [tex]\((0,0)\)[/tex] to [tex]\((1, \sqrt{3})\)[/tex].

5. Statement: The distance from [tex]\((0,0)\)[/tex] to [tex]\((1, \sqrt{3})\)[/tex] is [tex]\(\sqrt{(0-1)^2 + (0-\sqrt{3})^2} = \sqrt{1^2 + (\sqrt{3})^2} = \sqrt{1+3} = 2\)[/tex].
- Justification: Distance formula.

Finally, we draw our conclusion based on the computed distances.

6. Statement: Since [tex]\((1, \sqrt{3})\)[/tex] is 2 units from [tex]\((0,0)\)[/tex], it lies on a circle that is centered at the origin and contains the point [tex]\((0,2)\)[/tex].
- Justification: Definition of a circle.

Thus, we have shown step-by-step that the point [tex]\((1, \sqrt{3})\)[/tex] is indeed on the circle centered at [tex]\((0,0)\)[/tex] with radius 2.
We appreciate your presence here. Keep sharing knowledge and helping others find the answers they need. This community is the perfect place to learn together. IDNLearn.com is dedicated to providing accurate answers. Thank you for visiting, and see you next time for more solutions.