The length of a segment with endpoints  and  can be found using the distance formula with , , :

This is the length of one side of Square A; the area of the square is the square of this, or .

By similar reasoning, the length of a segment with endpoints  and  is

and the area of Square B is 

.

Since , and both are positive, it follows that 

Square B has the greater area.

It can be proved that the given information is insufficient to answer the question by looking at two cases.

Case 1: 

Square A has as a side a segment with endpoints at  and , the length of which can be found using the distance formula with , , :

This is the length of one side of Square A; the area of the square is the square of this, or 52.

Square B has as a side a segment with endpoints at  and , the length of which can be found the same way:

This is the length of one side of Square B; the area of the square is the square of this, or 50. This makes Square A the greater in area.

Case 2: 

Square A has as a side a segment with endpoints at  and ; this was found earlier to be a square of area 50.

Square B has as a side a segment with endpoints at  and , the length of which can be found using the distance formula with , , :

This is the length of one side of Square B; the area of the square is the square of this, or 52. This makes Square B the greater in area.

A diagonal of a square cuts the square into two isosceles right triangles, of which the diagonal is the common hypotenuse. Therefore, each figure is the hypotenuse of an isosceles right triangle with legs 10 inches, making them equal in length.

The diagonal of a square has length , or about 1.414, times the length of a side, which here is 600 feet; this makes the diagonal path about

 feet long.

Les runs around the square track twice, meaning that he runs the length of one side eight times; he also runs the length of the diagonal twice, This is a total of about

 feet.

Divide by 5,280 to convert to miles:

Of the given responses,  miles comes closest to the correct distance.

The diagonal of a square has length , or about 1.414, times the length of a side, which here is 700 feet; this makes the diagonal path about

 feet long.

We will call one complete circuit one running of the diagonal, which is 990 feet long, and one running around the square; the completion of one complete circuit amounts to running a distance of 

 feet.

Ellen seeks to run three miles, or 

 feet, which, divided by 3,790 feet, is about:

,

or four complete circuits and 0.17 of a fifth.

After four complete circuits, Ellen is backat Point A. She has yet to run

 feet. 

She will now run along the diagonal from Point A to Point C, but since the diagonal has length 990 feet, which is greater than 629 feet, she will finish running three miles when she is on this diagonal path.

The diagonal of a square has length , or about 1.414, times the length of a side, which here is 600 feet; this makes the diagonal path about

 feet long.

Kenny runs along this path twice, and he runs along the entire perimeter of the square path, so his run is about

 feet. Since one mile is equal to 5,280 feet, the greater quantity is (b).

The sidelength of a square is the square root of its area and one-fourth of its perimeter, so:

(a) A square with area 400 square inches has sidelength  inches.

(b) A square with perimeter 80 inches has sidelength  inches.

The two quantities are equal.

The sidelength of a square is the square root of its area and one-fourth of its perimeter, so:

(a) A square with area  square inches has sidelength  inches.

(b) A square with perimeter  inches has sidelength  inches.

(a) is the greater quantity.

Divide the perimeter of a square by 4 to get its sidelength:

The perimeter of a rectangle is twice the sum of its length and its width:

Since the height of the trapezoid in the figure is , both of its legs must have length greater than or equal to . But for a leg to be of length, it must be perpendicular to the bases. Since perpendicularity of both legs would make the trapezoid a rectangle - which it cannot be - it follows that both legs cannot be of length . Therefore, the perimeter of the trapezoid is:

The perimeter of the trapezoid must be greater than that of the rectangle.