Energy absorbing device

The invention claimed is: 1. An energy absorbing device comprising a first half hexagonal shaped piece of material and a second half hexagonal shaped piece of material joined together as a hexagonal shaped deformable elongate member, the hexagonal shaped deformable elongate member having a plurality of enhanced strength regions and having a plurality of untreated portions such that the device, in use, deforms in a stable, repeatable manner upon the absorption of impact energy associated with an impact; wherein the enhanced strength regions and the untreated portions of the deformable elongated member are integral with each of the first half and the second half hexagonal shaped pieces of material and arranged in an alternating manner, wherein the enhanced strength regions are surface-treated regions of each of the first half and the second half hexagonal shaped pieces of material, and wherein the untreated portions are non-treated regions of each of the first half and the second half hexagonal shaped pieces of material, wherein the enhanced strength regions have a nanocrystalline microstructure based on having been treated with a surface manipulation technique, where the surface manipulation technique is Surface Mechanical Attrition Treatment (SMAT), wherein the enhanced strength regions have a uniform width and thickness that is the same as a uniform width and thickness of the untreated portions of the deformable elongated member, wherein the enhanced strength regions have a first uniform height that is different from a second uniform height of the untreated portions of the deformable elongated member, and wherein the energy absorbing device has a sloped end, the sloped end having a sloped surface with an angle relative to a flat plane vertical to the energy absorbing device. 2. An energy absorbing device in accordance with claim 1 , wherein at least one of an interior portion and an exterior portion of the deformable elongate member is arranged to deform in a controlled manner. 3. An energy absorbing device in accordance with claim 2 , wherein the at least one of an interior and an exterior portion includes the enhanced strength regions, which enhanced strength regions are areas of non-uniform strength distribution. 4. An energy absorbing device in accordance with claim 3 , wherein the areas of non-uniform strength distribution have a yield strength at least 0.2% higher than the untreated portions. 5. An energy absorbing device in accordance claim 3 , wherein the areas of non-uniform strength distribution are formed by at least one of a laser sintering technique, a temperature annealing technique, a magnetic technique, the application of electric current, and the application of light. 6. An energy absorbing device in accordance with claim 3 , wherein the areas of non-uniform strength distribution are linearly shaped. 7. An energy absorbing device in accordance with claim 3 , wherein the areas of non-uniform strength distribution form a pattern. 8. An energy absorbing device in accordance with claim 1 , wherein a transverse cross section of the deformable elongate member is a polygon. 9. An energy absorbing device in accordance with claim 1 , including a first fastening plate attached to a first end of the deformable elongate member. 10. An energy absorbing device in accordance with claim 1 , including a second fastening plate attached to a second end of the deformable elongate member. 11. An energy absorbing device in accordance with claim 1 , wherein the deformable elongated member is arranged to provide an increased contact area during an early stage of the impact such that the deformable elongated member absorbs the impact energy gradually in an axial direction during the early stage of the impact. 12. An energy absorbing device in accordance with claim 1 , wherein the enhanced strength regions extend around the circumference of the hexagonal shaped deformable elongate member. 13. An energy absorbing device in accordance with claim 1 , wherein the sloped end is shaped to gradually increase the contact area at an early stage of impact so a reaction force applied on the hexagonal shaped deformable elongate member in an axial direction is gradually increased while at the same time reducing probability of a collapse starting from a rear portion of the hexagonal shaped deformable elongate member.