+1671 This is hard geometry!!
Two quarter-circles are drawn inside a unit square, as shown. A circle is drawn that is tangent to the quarter-circles, and a side of the square. Find the radius of the circle.
+397 Two methods.
Using CPhill's diagram,
E, H and D are collinear, (the line EHD is at rt-angles to the common tangent at E).
Let the radius of the small circle be c, then from the triangle GHD, c^2 + (1/2)^2 = HD^2,
so HD = sqrt(c^2 + 1/4),
so ED = HD + c = sqrt(c^2 + 1/4) + c = 1, (the radius of the big circle).
c^2 + 1/4 = (1 - c)^2 = 1 -2c + c^2,
2c = 3/4,
c = 3/8.
Let the radius of the small circle be c, then its Cartesian equation is
x^2 + (y - c)^2 = c^2
x^2 + y^2 -2yc = 0.................(1)
The equation of the big circle centre D is
(x - 1/2)^2 + y^2 = 1
x^2 - x + y^2 -3/4 = 0..................(2)
Solving simultaneously, (subtract (1) - (2)),
x - 2yc + 3/4 = 0.
Substitute for x in (1),
(2yc - 3/4)^2 + y^2 - 2yc = 0,
4y^2c^2 - 3yc + 9/16 + y^2 - 2yc = 0,
y^2(4c^2 + 1) - 5yc + 9/16 = 0.
For tangency, the equation needs to have a single root, so
25c^2 - 4(4c^2 +1)(9/16) = 0,
16c^2 - 9/4 = 0,
c^2 = 9/64,
c = 3/8.
+128475 
Let the intersection of the circle with the bottom edge of the square = ( 0 , 0) = G
Through this point draw lines y = -sqrt (3) x and y = sqrt (3) x
We can show that this will lead to the (approximate) radius of the circle
The equation of one circle is (x-.5)^2 + y^2 =1
And the intersection of this cirlce with the line y =sqrt (3) x can be found as
(x -.5)^2 + (sqrt (3) * x)^2 =1
Solving this for (x,y) produces ≈ (.3256 , .5641) = F
And using symmetry the intersection of the other circle with the line y = -sqrt (3) x is
(-.3256 , .5641) = E
The distance between these points is 2 (.3256) ≈ .651 = EF
And the distance between one of these intersection points and the intersection of the circle with the bottom of the square = sqrt [ (.3256)^2 + (.5641)^2 ] ≈ .651 = EG = FG
So we have an iinscribed equilateral triangle in the circle with sides ≈ .651
Angle EGF = 60° so angle EHF =120°
Using the Law of Cosines, we can find the (approximate) radius of the circle as follows
.651^2 = 2* r^2 - 2*(r^2) cos (120°)
.651^2 = 2r^2 - 2r^2 (-1/2)
.651^2 = 3r^2
r^2 = .651^2 / 3
r = sqrt [ .651^2 / 3 ] ≈ .3759
I'm sure that someone else may be able to give a more precise answer !!!!
+397 Two methods.
Using CPhill's diagram,
E, H and D are collinear, (the line EHD is at rt-angles to the common tangent at E).
Let the radius of the small circle be c, then from the triangle GHD, c^2 + (1/2)^2 = HD^2,
so HD = sqrt(c^2 + 1/4),
so ED = HD + c = sqrt(c^2 + 1/4) + c = 1, (the radius of the big circle).
c^2 + 1/4 = (1 - c)^2 = 1 -2c + c^2,
2c = 3/4,
c = 3/8.
Let the radius of the small circle be c, then its Cartesian equation is
x^2 + (y - c)^2 = c^2
x^2 + y^2 -2yc = 0.................(1)
The equation of the big circle centre D is
(x - 1/2)^2 + y^2 = 1
x^2 - x + y^2 -3/4 = 0..................(2)
Solving simultaneously, (subtract (1) - (2)),
x - 2yc + 3/4 = 0.
Substitute for x in (1),
(2yc - 3/4)^2 + y^2 - 2yc = 0,
4y^2c^2 - 3yc + 9/16 + y^2 - 2yc = 0,
y^2(4c^2 + 1) - 5yc + 9/16 = 0.
For tangency, the equation needs to have a single root, so
25c^2 - 4(4c^2 +1)(9/16) = 0,
16c^2 - 9/4 = 0,
c^2 = 9/64,
c = 3/8.
