Is 2x-3Y<x^2
1) 2x-3y=-2
2) x>2 and Y>0
Can you help me understand how I approach the 2nd statement?
Thanks,
Mariela :shock:
GMAT Forum
5 postsPage 1 of 1
- Mariela
- GMAT 5/18
Mariela,
This is how I would solve the question:
(I) Is -2 < x^2 ? Yes, because anything to the power of 2 is going to be either 0 or positive. Therefore, sufficient.
(II) I would test out a couple of numbers here.
Test 1:
X = 2.1 and Y = 0.1
2(2.1) - 0.3 < (2.1)^2 True
Test 2:
X = 2.1 and Y = 100
2(2.1) - 300 < (2.1)^2 True
Test 3:
X = 100 and Y = 0.1
200 - 0.3 < 100^2 True
Test 4:
X = 100 and Y = 100
200 - 300 < 100^2 True
I am pretty sure there are better ways to solve, but this is how I would approach it and I would select answer D. It took less than 2 minutes. :)
Hope that helps!
This is how I would solve the question:
(I) Is -2 < x^2 ? Yes, because anything to the power of 2 is going to be either 0 or positive. Therefore, sufficient.
(II) I would test out a couple of numbers here.
Test 1:
X = 2.1 and Y = 0.1
2(2.1) - 0.3 < (2.1)^2 True
Test 2:
X = 2.1 and Y = 100
2(2.1) - 300 < (2.1)^2 True
Test 3:
X = 100 and Y = 0.1
200 - 0.3 < 100^2 True
Test 4:
X = 100 and Y = 100
200 - 300 < 100^2 True
I am pretty sure there are better ways to solve, but this is how I would approach it and I would select answer D. It took less than 2 minutes. :)
Hope that helps!
- Jeff
Is 2x-3Y<x^2
1) 2x-3y=-2
2) x>2 and Y>0
Mariela -
To answer whether (2) is sufficient by itself, it helps to rearrange the original inequality (rephase the question):
2x-3y<x^2
2x-x^2<3y
x(2-x)<3y
Given the inequality above consider (2): If x>2, then the left side of the inequality is always negative, because the x is positive and the quantity (2-x) will be negative. If y>0 then the quantity 3y is always positive, so it will always be the case that 2x-3y<x^2 and (2) by itself is sufficient to answer the question.
Plugging in numbers like the previous poster did is a perfectly valid way to approach these problems - but you have to be v. careful not to miss a region of interest when choosing numbers to test. If you become comfortable and quick with algebra, it can often give you a definitive answer quickly. One important caveat: Be v. careful manipulating inequalities that contain variables that might or might not be negative. In the example above the inequality was manipulated using addition and subtraction only - if you divide or multiply by a variable or quantity that might or might not be negative, you have to account for both cases and remember to flip the inequality sign accordingly.
Best,
Jeff[/i][/b]
1) 2x-3y=-2
2) x>2 and Y>0
Mariela -
To answer whether (2) is sufficient by itself, it helps to rearrange the original inequality (rephase the question):
2x-3y<x^2
2x-x^2<3y
x(2-x)<3y
Given the inequality above consider (2): If x>2, then the left side of the inequality is always negative, because the x is positive and the quantity (2-x) will be negative. If y>0 then the quantity 3y is always positive, so it will always be the case that 2x-3y<x^2 and (2) by itself is sufficient to answer the question.
Plugging in numbers like the previous poster did is a perfectly valid way to approach these problems - but you have to be v. careful not to miss a region of interest when choosing numbers to test. If you become comfortable and quick with algebra, it can often give you a definitive answer quickly. One important caveat: Be v. careful manipulating inequalities that contain variables that might or might not be negative. In the example above the inequality was manipulated using addition and subtraction only - if you divide or multiply by a variable or quantity that might or might not be negative, you have to account for both cases and remember to flip the inequality sign accordingly.
Best,
Jeff[/i][/b]
- GMAT 5/18
Beautiful, Jeff!
Yes, using a plug and play method is risky as you may miss a region (as Jeff stated).
Mariela, I would suggest trying to solve something algebraically first, but do not spend a lot of time if you get nowhere or cannot "see" the algebraic solution; if you get stuck, fall back to the plug and play.
Yes, using a plug and play method is risky as you may miss a region (as Jeff stated).
Mariela, I would suggest trying to solve something algebraically first, but do not spend a lot of time if you get nowhere or cannot "see" the algebraic solution; if you get stuck, fall back to the plug and play.
- esledge
- Forum Guests
- Posts: 1181
- Joined: Tue Mar 01, 2005 6:33 am
- Location: St. Louis, MO
Graphing would work, too.
Good solutions, and excellent point about the potential pitfalls of plug-and-play.
Although hard to reproduce here, you may want to try this on your own: graphing.
The question rephrases to "Is y > (2/3)x - x^2?" Plot (2/3)x - x^2 and you get an upside-down "U" centered just to the right of the y-axis, with the base of the "U" just above the x-axis. The visual interpretation of the rephrase is "Are all of the points (x, y) in the region above the 'U'?"
(1) Rephrases to the equation of a line y = (2/3)x + 2/3, which crosses the y-axis at 2/3 (above the "U") and has a slope of 2/3. The entire line is above the "U." SUFFICIENT.
(2) The rectangularly bounded region to the right of x = 2 and above y = 0. This entire region is above the "U," too. SUFFICIENT.
Obviously, this method is not required for this problem, and there is a little set-up time involved in drawing the "U." Such a method could be a life-saver on a problems with more complicated constraints, or when you want to plug-and-play but have no idea what values to try. Also, some people are more visually inclined and can follow this approach better than the algebraic one.
Although hard to reproduce here, you may want to try this on your own: graphing.
The question rephrases to "Is y > (2/3)x - x^2?" Plot (2/3)x - x^2 and you get an upside-down "U" centered just to the right of the y-axis, with the base of the "U" just above the x-axis. The visual interpretation of the rephrase is "Are all of the points (x, y) in the region above the 'U'?"
(1) Rephrases to the equation of a line y = (2/3)x + 2/3, which crosses the y-axis at 2/3 (above the "U") and has a slope of 2/3. The entire line is above the "U." SUFFICIENT.
(2) The rectangularly bounded region to the right of x = 2 and above y = 0. This entire region is above the "U," too. SUFFICIENT.
Obviously, this method is not required for this problem, and there is a little set-up time involved in drawing the "U." Such a method could be a life-saver on a problems with more complicated constraints, or when you want to plug-and-play but have no idea what values to try. Also, some people are more visually inclined and can follow this approach better than the algebraic one.
Emily Sledge
Instructor
ManhattanGMAT
Instructor
ManhattanGMAT
5 posts Page 1 of 1