Polymer scaffolds having a low crossing profile

What is claimed is: 1. A method, comprising: using a balloon having an inflated diameter (Di); using a bioabsorbable scaffold having a pre-crimp diameter (Dpc), the scaffold formed from a tube comprising a bioabsorbable polymer; and crimping the scaffold to the balloon; wherein the scaffold and balloon satisfy the following equation: 1.1×( Di )×(1.2) −1 ≦Dpc ≦1.7×( Di )×(1.2) −1 , and wherein the scaffold comprises a set of longitudinally spaced rings formed by struts and crowns, the struts configured to fold towards and unfold away from each other at the crowns, and the set of longitudinally spaced rings including a proximal end ring, a distal end ring opposing the proximal end ring, and interior rings positioned between the end rings, wherein each ring is associated with its direct neighboring ring by links. 2. The method of claim 1 , wherein the crowns have a pre-crimped crown angle of less than 115 degrees. 3. The method of claim 1 , wherein each strut has an aspect ratio (AR) of 0.8 to 1.4, AR being defined as a ratio of width to thickness and wherein each link has an aspect ratio of (AR) 0.4 to 0.9. 4. The method of claim 1 , wherein at least one pair of neighboring interior rings is adjoined by middle links, each middle link is associated with one crown of one ring and another crown of the neighboring ring, such that each middle link and its corresponding crown for the one ring form a generally “Y” shaped structure and each middle link and its corresponding crown for the neighboring ring form a generally “W” shaped structure. 5. The method of claim 1 , wherein at least some of the interior rings have sinusoidal segments and a repeating pattern of “Y” shaped and “W” shaped crowns where the sinusoidal segments meet the links, and wherein the pattern further includes a crown that is link-free between each “Y” and “W” shaped crown. 6. The method of claim 1 , wherein the links between a first pair of rings are out of phase or circumferentially off-set from the links between a second pair of rings, the first pair of rings and the second pair of rings sharing a common interior ring; and wherein the links between the first pair of rings are in phase or not circumferentially off-set from the links between a third pair of rings, the second pair of rings and the third pair of rings sharing a common interior ring. 7. The method claim 1 , comprising a first ring, a second ring next to the first ring, a third ring next to the second ring, the second ring being in between the first and third rings, and a fourth ring next to the third ring, the third ring being in between the second and fourth rings, wherein the links between the first ring and the second ring are circumferentially offset from the links between the second ring and third ring, wherein the links between the second ring and the third ring are circumferentially offset from the links between the third ring and the fourth ring, and wherein the links between the first ring and the second ring are aligned with and not circumferentially offset from the links between the third ring and fourth ring, all links running along a longitudinal, central axis of the scaffold made from the rings and links. 8. The method of claim 1 , wherein a space bounded by portions of at least one pair of longitudinally spaced neighboring interior rings and circumferentially spaced links connecting the pair of interior rings form a W-shaped closed cell. 9. The method of claim 8 , wherein the at least one pair of the longitudinally spaced neighboring interior rings forms only 4 W-shaped closed cells. 10. The method of claim 9 , wherein each of the closed cells consists of 4 link-free crowns. 11. The method of claim 1 , wherein the scaffold comprises a first ring, a second ring, and a third ring, the second ring being positioned between the first and third rings, and wherein the first and second rings, including the links there between, define a first set of W-shaped closed cells, wherein the second and third rings, including the links there between, define a second set of W-shaped closed cells, and wherein the W-shaped closed cells of the first set are circumferentially off-set from the W-shaped closed cells of the second set. 12. The method of claim 11 , wherein the first set consists of 4 closed cells and the second set consists of 4 closed cells, and further wherein each cell consists of 4 crowns that are not connected to any links. 13. The method of claim 1 , wherein at least one of the links of the scaffold comprises a marker structure for holding a pair of markers, the marker structure includes a pair of depots in which the markers are placed, the depots being placed in a planar view along a vertical axis (B-B) perpendicular to a longitudinal axis (A-A); and wherein the set of rings includes a minimum crimped diameter (MCD) such that in the minimum crimped diameter, a pair of rings, between which the marker structure resides, do not make contact with the marker structure. 14. The method of claim 13 , wherein the minimum crimped diameter (MCD) is an inner diameter of the scaffold when the following step is performed: bending the struts of the rings towards each other, wherein the struts bend at the crowns, such that after bending, at least one of a pair of struts adjoined by a crown is separated by a distance of about zero or the at least one pair of struts are touching each other. 15. The method of claim 13 , wherein each link adjoins a pair of the neighboring rings at a crown of each ring, and wherein the minimum crimped diameter (MCD) is equal to a value derived from equation 1 for struts having an essentially square cross-section or from equation 2 for struts having a trapezoidal cross-section: (Σ Swi+ΣCrj+ΣLwk )*(π) −1 +2* WT   (equation 1) (Σ Swi+ΣCrj+ΣLwk )*(π −1   (equation 2) wherein ΣSwi (i=1 . . . n) is the sum of n ring struts having width Swi; ΣCrj (j=1 . . . m) is the sum of m crown inner radii having radii Crj (times 2); ΣLwk (k=1 . . . p) is the sum of p links having width Lwk; and WT is a ring wall thickness. 16. The method of claim 13 , wherein each link adjoins a pair of the neighboring rings at a crown of each ring, and wherein the minimum crimped diameter (MCD) is less than a value derived from equation 1 for struts having an essentially square cross-section or from equation 2 for struts having a trapezoidal cross-section: (Σ Swi+ΣCrj+ΣLwk )*(π) −1 +2* WT   (equation 1) (Σ Swi+ΣCrj+ΣLwk )*(π −1   (equation 2) wherein ΣSwi (i=1 . . . n) is the sum of n ring struts having width Swi; ΣCrj (j=1 . . . m) is the sum of m crown inner radii having radii Crj (times 2); ΣLwk (k=1 . . . p) is the sum of p links having width Lwk; and WT is a ring wall thickness. 17. The method of claim 1 , wherein a space bounded by portions of at least one pair of longitudinally spaced neighboring interior rings and circumferentially spaced links connecting the pair of interior rings form a W-V shaped closed cell. 18. The method of claim 17 , wherein the at least one pair of the longitudinally spaced neighboring interior rings forms only 3 W-V shaped closed cells. 19. The method of claim 1 , comprising a first ring, a second ring, and a third ring, the second ring being positioned between the first and third rings, and wherein the first and second rings, including the links there between, define a first set of W-V shaped closed cells, wherein the second and third rings, including the links there between, define a second s