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 GMAT 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.

It appears that you are browsing the GMAT Club forum unregistered!

Signing up is free, quick, and confidential.
Join other 500,000 members and get the full benefits of GMAT Club

Registration gives you:

Tests

Take 11 tests and quizzes from GMAT Club and leading GMAT prep companies such as Manhattan GMAT,
Knewton, and others. All are free for GMAT Club members.

Applicant Stats

View detailed applicant stats such as GPA, GMAT score, work experience, location, application
status, and more

Books/Downloads

Download thousands of study notes,
question collections, GMAT Club’s
Grammar and Math books.
All are free!

Thank you for using the timer!
We noticed you are actually not timing your practice. Click the START button first next time you use the timer.
There are many benefits to timing your practice, including:

x^2+y^2=5 , so it is a circle with (0,0) as its orgin, with radius equal to 5^0.5 = 2.2 approx.

The 4 vertix (typo?) of the circles are exactly the 4 intercepts with the x-, y- axis.

So the 4 vertix are (2.2,0), (0,-2.2), (-2.2,0), and (0,2.2)

Let's go through the circumference, starting from (2.2,0), in clockwise direction: the first point on the circumference with integer coordinates is: (2,-1) (1,-2) (-1,-2) (-2,-1) (-2,1) (-1,2) (1,2) (2,1)

x^2+y^2=5 , so it is a circle with (0,0) as its orgin, with radius equal to 5^0.5 = 2.2 approx.

The 4 vertix (typo?) of the circles are exactly the 4 intercepts with the x-, y- axis.

So the 4 vertix are (2.2,0), (0,-2.2), (-2.2,0), and (0,2.2)

Let's go through the circumference, starting from (2.2,0), in clockwise direction: the first point on the circumference with integer coordinates is: (2,-1) (1,-2) (-1,-2) (-2,-1) (-2,1) (-1,2) (1,2) (2,1)

Answer is 8C)

Sorry, I overlook the question, it is concern about semi-circle.

My answer would be 4 (A) (2,-1) (1,-2) (-1,-2) (-2,-1)

How many points on the circumference of a semi-circle represented with x^2+y^2=5 have integer coordinates? (A) 4 (B) 6 (C) 8 (D) 12 (E) 16

just thought i'd present a lil twist to a problem ritula posted

I have an issue with your problem. As long as the diameter of the semi-circle is parallel to an axis, the answer is 4, but it is possible to define semi-circles centered on the origin that pass through 5 integer coordinates ( e.g. m = -1/2 ).

How many points on the circumference of a semi-circle represented with x^2+y^2=5 have integer coordinates? (A) 4 (B) 6 (C) 8 (D) 12 (E) 16

just thought i'd present a lil twist to a problem ritula posted

I have an issue with your problem. As long as the diameter of the semi-circle is parallel to an axis, the answer is 4, but it is possible to define semi-circles centered on the origin that pass through 5 integer coordinates ( e.g. m = -1/2 ).

But 5 is not a given option. Unless you want to pass the question, u have to take the one that makes most sense.

An interesting approach. I interpreted the "circumference of a semi-circle" as referring only to the curved part of the figure. I wonder if there is a rule for it. Still, wouldn't your interpretation yield nine points when (0,0) is counted?

I would have never caught the semi-circle catch in the question but yeah agree with you that answer should be 4. with 8c4 = 70 different possibilities..

I have an issue with your problem. As long as the diameter of the semi-circle is parallel to an axis, the answer is 4, but it is possible to define semi-circles centered on the origin that pass through 5 integer coordinates ( e.g. m = -1/2 ).

I have an issue with your problem. As long as the diameter of the semi-circle is parallel to an axis, the answer is 4, but it is possible to define semi-circles centered on the origin that pass through 5 integer coordinates ( e.g. m = -1/2 ).

could you expand on that? what is m?

"m" is the common abbreviation for slope.

1) plot all eight answers for the original equation 2) draw circle through all eight points. 3) draw a line from (-2,1) to (2,-1). This line will pass through the origin and will have a slope of -1/2. 4) consider this line the diameter of the semi-circle. 5) the semi circle now passes through 5 points: (-2,1) (-1,2) (1,2) (2,1) (2,-1)