Balloon and method of manufacturing the same

What is claimed is: 1. A balloon configured to be arranged on a medical catheter, comprising: a dilatable cylindrical portion that is formed with a birefringent polymer material, the dilatable cylindrical portion being configured such that a ratio of a number of orientation distributions calculated by dividing a number of orientation distributions throughout a total length of the cylindrical portion in a circumferential direction by a number of orientation distributions throughout a total length of the cylindrical portion in an axial direction is less than 2, whereby a rupture of the dilatable cylindrical portion in the circumferential direction is prevented. 2. The balloon according to claim 1 , wherein the cylindrical portion has a multi-layer structure, the birefringent polymer material including a plurality of polymer materials which are different from each other. 3. The balloon according to claim 2 , wherein fluctuation in the axial direction in the ratio of the number of orientation distributions in each layer of the multi-layer structure having a maximum strength is 1 or less in terms of a standard deviation. 4. The balloon according to claim 1 , wherein the balloon further includes a tapered portion on each end of the dilatable cylindrical portion. 5. The balloon according to claim 1 , wherein an outer diameter of the dilatable cylindrical portion is 1.0mm to 10 mm. 6. The balloon according to claim 1 , wherein when a refractive index in a circumferential direction r, a refractive index in a thickness direction d, and a refractive index in an axial direction I are respectively indicated as nr, nd, and nl, n x and n z required for calculating the number of orientation distributions in the circumferential direction, the number of orientation distributions in the axial direction, and the number of orientation distributions in the thickness direction are calculated by the following Expressions 2, utilizing intrinsic refringence Δn* as a value of birefringence shown when molecules are oriented 100%: Expressions 2 n z =|Δn length|/Δ n*   (5) n x =|Δn axis|/Δ n*   (6) |Δ n length|=| nl−nd|   (7) |Δ n axis|=| nr−nd|   (8) n 2 =( nr 2 +nd 2 +nl 2 )/3  (9) wherein, n 2 indicates average refractive index. 7. The balloon according to claim 6 , wherein the number of orientation distributions in the circumferential direction, the number of orientation distributions in the axial direction, and a number of orientation distributions in a thickness direction are defined by the following Expressions 1: cos 2 Ø x + cos 2 Ø y + cos 2 Ø z =1  (1) cos 2 Ø x =n z + cos 2 Ø y   (2) cos 2 Ø z =n x + cos 2 Ø y   (3) (1 −n x −n z )/3= cos 2 Ø y   (4)  wherein cos 2 Ø x indicates the number of orientation distributions in the circumferential direction, cos 2 Ø y indicates the number of orientation distributions in the thickness direction, and cos 2 Ø z indicates the number of orientation distributions in the axial direction. 8. A medical catheter including the balloon according to claim 1 , wherein the medical catheter is a balloon catheter. 9. The medical catheter according to claim 8 , wherein the balloon catheter is used in order to cause a stent to indwell inside a human body.