Last visit was: 21 Nov 2024, 10:31 It is currently 21 Nov 2024, 10:31

Close

GRE Prep Club Daily Prep

Thank you for using the timer - this advanced tool can estimate your performance and suggest more practice questions. We have subscribed you to Daily Prep Questions via email.

Customized
for You

we will pick new questions that match your level based on your Timer History

Track
Your Progress

every week, we’ll send you an estimated GRE score based on your performance

Practice
Pays

we will pick new questions that match your level based on your Timer History

Not interested in getting valuable practice questions and articles delivered to your email? No problem, unsubscribe here.

Close

Request Expert Reply

Confirm Cancel
Verbal Expert
Joined: 18 Apr 2015
Posts: 30000
Own Kudos [?]: 36335 [6]
Given Kudos: 25923
Send PM
avatar
Intern
Intern
Joined: 21 Apr 2017
Posts: 3
Own Kudos [?]: 1 [0]
Given Kudos: 0
Send PM
avatar
Retired Moderator
Joined: 20 Apr 2016
Posts: 1307
Own Kudos [?]: 2273 [4]
Given Kudos: 251
WE:Engineering (Energy and Utilities)
Send PM
avatar
Director
Director
Joined: 03 Sep 2017
Posts: 518
Own Kudos [?]: 703 [0]
Given Kudos: 0
Send PM
Re: Triangle ABC is inscribed in a semicircle centered at [#permalink]
Since the triangle ABC is built on the diameter, the angle in B is equal to 90°.

Then, moving to triangle BCD, it is easy to notice that sides BD and DC are equal since they are both radii of the circumference, thus the triangle is at least isosceles.

Since the angle in D is 60°, the other two angles (which are equal) are (180°-60)/2 = 60°. Thus the triangle is actually equilateral.

Now, moving back to triangle ABC, we have now two angles, 90° in B and 60° in C. Thus, the last angle must be 30° (180°-60°-30°). Thus, triangle ABC is a 30-60-90.

Then, we know that the longer leg is computed as \(l\sqrt(3)\), thus equating this expression to 6, we get \(l = 2\sqrt(3)\).

Finally, we can compute the area as \(\frac{6*2sqrt(3)}{2} = 6\sqrt(3)\)

Answer B
avatar
Intern
Intern
Joined: 07 Jan 2019
Posts: 30
Own Kudos [?]: 2 [0]
Given Kudos: 0
Send PM
Re: Triangle ABC is inscribed in a semicircle centered at [#permalink]
thanks
Manager
Manager
Joined: 05 Aug 2020
Posts: 101
Own Kudos [?]: 244 [0]
Given Kudos: 14
Send PM
Re: Triangle ABC is inscribed in a semicircle centered at [#permalink]
1
Carcass wrote:

Triangle ABC is inscribed in a semicircle centered at D. What is the area of tri­angle ABC ?

A. \(\frac{12}{\sqrt{3}}\)

B. \(6 \sqrt{3}\)

C. 12

D. \(12 \sqrt{3}\)



This is a great question - there are many different geometry properties tested at once here. I'd refer to pranab's picture in conjuction with this explanation.

First off, notice that triangle \(ABC\) is inscribed in a semicircle with a side as its diameter. This must mean that angle \(ABC\) is 90 degrees..

Also notice that angle \(ADB\) is 180-60 = 120. \(AD\) and \(AB\) are both radius' of the semicircle, and so triangle \(ADB\) is an isosceles triangle.

We'll denote the radius of the semicircle \(r\). So we can let \(AD\) and \(AB\) be length \(r\).

Since triangle \(ADB\) is isosceles, this means that angle \(DAB\) and \(ABD\) are the same. Let their angles b \(x\).

So:

\(2x + 120 = 180\)
\(2x = 60\)
\(x = 30\)

Now recall from above in purple, that angle \(ABC\) is 90 degrees. Since angle \(ABD\) = 30, angle \(DBC\) = 60. This must mean that angle \(CAB\) = 60, and triangle \(DBC\) is an equilateral triangle.

We already know that \(DB\) is the radius \(r\). It's clear that \(DC\) is also the radius \(r\). But since triangle \(DBC\) is an equilateral triangle, we know that \(BC\) is also the length of the radius \(r\).

To continue, we'll have to break this equilateral triangle into two 30-60-90 triangles, so bring a vertical line down the middle of triangle \(DBC\).

The base of this triangle is now \(\frac{r}{2}\). Using the \(x:x\sqrt{3}:2x\) ratio, we know that the length of the vertical line we drew must be \(r\sqrt{3} * \frac{1}{2}\).

So we have the dimensions of this new small right triangle. From the beginning, in purple, we know that triangle \(ABC\) is a right triangle as well. We can use the similar triangle property to proceed.

So we have the height of triangle \(ABC\) = 6, and its base is \(r\). The small right triangle has a height of \(r\sqrt{3} * \frac{1}{2}\) and a base of \(\frac{r}{2}\).


So we can set up the following proportion:

\(\frac{height}{base}\) of triangle \(ABC\) = \(\frac{height}{base}\) of new small right triangle.

\(\frac{6}{r}\) = \((r\sqrt{3} * \frac{1}{2})\) / \((\frac{r}{2})\)

\(\frac{6}{r}\) = \(r\sqrt{3} * \frac{1}{2} * \frac{2}{r}\)

\(\frac{6}{r}\) = \(\sqrt{3}\)

\(\frac{6}{\sqrt{3}}\) = \(r\)

Simplifying:

\(2\sqrt{3} = r\)

So we've found the length of the radius!

Going back to right triangle \(ABC\), we see that the base is the length \(BC\), which we know is \(2\sqrt{3}\), and the height which is 6.

To find the area:

\(\frac{bh}{2} = Area\)

\(6*2\sqrt{3} * \frac{1}{2} = Area\)

\(6\sqrt{3} = Area\)


So the answer is B.
User avatar
GRE Prep Club Legend
GRE Prep Club Legend
Joined: 07 Jan 2021
Posts: 5028
Own Kudos [?]: 74 [0]
Given Kudos: 0
Send PM
Re: Triangle ABC is inscribed in a semicircle centered at [#permalink]
Hello from the GRE Prep Club BumpBot!

Thanks to another GRE Prep Club member, I have just discovered this valuable topic, yet it had no discussion for over a year. I am now bumping it up - doing my job. I think you may find it valuable (esp those replies with Kudos).

Want to see all other topics I dig out? Follow me (click follow button on profile). You will receive a summary of all topics I bump in your profile area as well as via email.
Prep Club for GRE Bot
Re: Triangle ABC is inscribed in a semicircle centered at [#permalink]
Moderators:
GRE Instructor
83 posts
GRE Forum Moderator
37 posts
Moderator
1111 posts
GRE Instructor
234 posts

Powered by phpBB © phpBB Group | Emoji artwork provided by EmojiOne