Saturday, June 27, 2020
3 Ways to Solve a 750+ Level GMAT Question About Irregular Polygons
We have examined how to deal with polygons when you encounter them on a GMAT question in a previous post.à Today, we will look at a relatively difficult polygon question, however we would like to remind you here that the concepts being tested in this question are still very simple (although we wont give away exactly which concepts they are yet). First, take a look at the question itself: The hexagon above has interior angles whose measures are all equal. As shown, only five of the six side lengths are known: 10, 15, 4, 18, and 7. What is the unknown side length? (A)à 7 (B)10 (C) 12 (D) 15 (E) 16 There are various ways to solve this question, but each takes a bit of effort. Note that the polygon we are given is not a regular polygon, since the side lengths are not all equal. The angles, however,à are all equal. Letââ¬â¢s first find the measure of each one of those angles using the formula discussed inà this previous post. (n 2)*180 = sum of all interior angles (6 2)*180 = 720 Each of the 6 angles = 720/6 = 120 degrees Though we would like to point out here that if you see a question such as this one on the actual GMAT exam, you should already know that if each angle of a hexagon is equal, each angle must be 120 degrees, so performing the above calculation would not be necessary. Method 1: Visualization This is a very valid approach to obtaining the correct answer on thisà GMAT question since we donââ¬â¢t need to explain the reasoning or show ourà steps, howeverà it may be hard to comprehend for the beginners. We will try to explain it anyway, since it requires virtuallyà no work and will help build your math instinct. Note that inà the given hexagon, each angle is 120 degrees this means that each pair of opposite sides are parallel. Think of it this way: Side 4 turns on Side 18 by 120 degrees. Then Side 15 turns on Side 4 by another 120 degrees. And finally, Side 10 turns on Side 15 by another 120 degrees. So Side 10 has, in effect, turned by 360 degrees on Side 18. This means Side 10 is parallel to Side 18. Now, think of the 120 degree angle between Side 4 and Side 15à it has to be kept constant. Plus, the angles of the legs must also stay constant at 120 degrees with Sides 10 and 18. Since the slopes of each leg of that angleà are negatives of each other (âËÅ¡3 and -âËÅ¡3), when one leg gets shorter, the other gets longer by the same length (use the image below as a visual of what were talking about). Hence, the sum of the sides will always be 15 + 4 = 19. This means 7 + Unknown = 19, soà Unknown = 12. Our answer is C. If you struggled to understand the approach above, youre not alone. This method involves a lot of intuition, and struggling to figure it out may not be the best use of your time on the GMAT, so letââ¬â¢s examineà a couple of more tangible solutions! Method 2: Using Right Triangles As we sawà in Method 1 above, AB and DE are parallel lines. Since each of the angles A, B, C, D, E and F are 120 degrees, the four triangles we have made are all 30-60-90 triangles. The sides of a 30-60-90 triangle can be written usingà the ratio 1:âËÅ¡(3):2. AT = 7.5*âËÅ¡3 and ME = 2*âËÅ¡3, so the distance between the sides of length 10 and 18 is 9.5*âËÅ¡3. We know that DN = 3.5*âËÅ¡3, so BP = (9.5*âËÅ¡3) (3.5*âËÅ¡3) = 6*âËÅ¡3. Since the ratios of our sides should be 1:âËÅ¡(3):2, side BC = 2*6 = 12. Again, the answer is C. Lets look at our third and final method for solving this problem: Method 3: Using Equilateral Triangles First, extend the sides of the hexagon as shown to form a triangle: Since each internal angle of the hexagon is 120 degrees, each external angle will be 60 degrees. In that case, each angle between the dotted lines will become 60 degrees too, and hence, triangle PAB becomesà an equilateral triangle. This means PA = PB = 10. Triangle QFE à and triangle RDC also become equilateral triangles, so QF = QE = 4, andà RD = RC = 7. Now note that since angles P, Q, and R are all 60 degrees, triangle PQR is also equilateral, and hence, PQ = PR. PQ = 10 + 15 + 4 = 29 PR = 10 + BC + 7 = 29 BC = 12 (again, answer choice C) Note the geometry concepts that we used to solve this problem: regular polygon, parallel lines, angles, 30-60-90 right triangles, and equilateral triangles. We know all of these concepts very well individually, but applying them to a GMAT question can take some ingenuity! Getting ready to take the GMAT? We haveà free online GMAT seminarsà running all the time. And, be sure to follow us onà Facebook,à YouTube,à Google+, andà Twitter! Karishma, a Computer Engineer with a keen interest in alternative Mathematical approaches, has mentored students in the continents of Asia, Europe and North America. She teaches theà GMATà for Veritas Prep and regularly participates in content development projects such asà this blog!
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