I had a solution like Steven but after seeing the result I decided to try a geometric approach.

  A
 /|\
B-+-C
| F |
|/ \|
E---D

Let the circumcenter of triangle ADE be point F. Point F will be on the bisector of angle EAD, which is also the bisector of angle BAC.  Angle BAF = (angle BAC)/2 = 30 degrees.

Triangle ABE is isosceles with AB=BE.  Angle ABE = angle ABC + angle CBE = 150 degrees.  Then angle BAE = (180 - angle ABE)/2 = 15 degrees.

Triangle AFE is isosceles with AF=FE and angle EAF = angle AEF.  Angle AEF = angle BAC - angle BAE = 15 degrees.

Then triangles ABE and AFE have base angles with the same measure of 15 degrees and have the same base AE.  Therefore their legs are equal: AB=AE=AF=FE.

AF and FE are radii of the circumcircle thus the circumcircle of ABE has a radius of the same length as the sides of ABC and BCDE.

B---C
|\ /|
| A |
E---D
 \ /
  F

Let the circumcenter of triangle ADE be point F.  Angle EFD is a central angle and subtends arc EAD.  Triangle EFD is isosceles with vertex angle EFD.

EBA is an isosceles triangle with BE=BA and vertex angle EBA.  Angle EBA = angle CBE + angle ABE = 30 degrees.  Then angle BAE = (180 - angle ABE)/2 = 75 degrees.

Similarly, angle CAD is also 75 degrees.

Angle EAD = 360 degrees - angle BAE - angle CAD - angle BAC = 150 degrees. 

Angle EAD is an inscribed angle of the curcumcircle and subtends arc EA.  Arc EA = 2 * angle EAD = 300 degrees. Arc EAD is the supplementary arc to arc EA, then arc EAD = 360 degrees - arc EA = 60 degrees.  

Angle EFD = arc EAD = 60 degrees.  Then triangle EFD is equilateral which implies ED=EF=DF.  

DF and FE are radii of the circumcircle thus the circumcircle of ABE has a radius of the same length as the sides of ABC and BCDE.