Vibratory bandgap device

What is claimed is: 1. A vibratory isolator, comprising: a periodic alternating structure comprising: a plurality of mass inertia components, wherein at least one mass inertia component comprises a disk; and a plurality of compliant components attaching adjacent mass inertia components to each other, wherein at least one compliant component comprises a ring, wherein at least one ring is sandwiched between two disks, and wherein at least one ring is in contact with at least two disks, the periodic alternating structure alternating between the disks and the rings, the vibratory isolator providing a vibratory bandgap having a range of frequencies through which vibrations cannot pass, the vibratory bandgap being bounded by an upper rocking mode frequency of approximately 85 Hertz (Hz), the vibratory bandgap being bounded by a lower shearing mode frequency of approximately 60 Hertz (Hz). 2. The vibratory isolator of claim 1 , wherein each ring is in contact with at least two disks. 3. The vibratory isolator of claim 1 , wherein each ring is in contact with exactly two disks. 4. The vibratory isolator of claim 1 , wherein each ring is sandwiched between two disks. 5. The vibratory isolator of claim 1 , wherein a top disk is in contact with one ring, a bottom disk is in contact with one ring, and each of the other disks is in contact with two rings except a top disk and a bottom disk. 6. The vibratory isolator of claim 1 , wherein at least one disk has a diameter D M that is larger than a diameter D o of at least one ring. 7. The vibratory isolator of claim 6 , wherein each ring has a diameter D o , and wherein each disk has a diameter D M that is larger than the diameter D o of each ring. 8. The vibratory isolator of claim 6 , wherein D m , is approximately 10 inches, and D o is approximately 2 inches. 9. The vibratory isolator of claim 1 , wherein at least one ring comprises at least one of an o-ring and a spring. 10. The vibratory isolator of claim 1 , wherein at least one ring has an axial stiffness of approximately 1.1×10 6 newtons per meter (N/M), and wherein at least one ring has a shear stiffness of approximately 2.1×10 5 N/M. 11. The vibratory isolator of claim 1 , wherein at least one disk is approximately ½ inches thick, and wherein at least one disk comprises aluminum. 12. The vibratory isolator of claim 1 , wherein the vibratory isolator comprises 5 disks, and wherein the vibratory isolator further comprises 4 rings. 13. The vibratory isolator of claim 1 , wherein the upper frequency comprises a shearing mode lower frequency. 14. The vibratory isolator of claim 13 , wherein the shearing mode lower frequency is adjustable by adjusting a ratio of a mass of at least one disk and a shear stiffness of at least one spring. 15. The vibratory isolator of claim 1 , wherein the lower frequency comprises a rocking mode upper frequency. 16. The vibratory isolator of claim 15 , wherein the rocking mode upper frequency is adjusted by adjusting a ratio of D m to D o . 17. A vibratory isolator, comprising: a periodic alternating structure comprising: a plurality of mass inertia components, wherein at least one mass inertia component comprises a disk; and a plurality of compliant components attaching adjacent mass inertia components to each other, wherein at least one compliant component comprises a ring, wherein a top disk is in contact with one ring, a bottom disk is in contact with one ring, and each of the other disks is in contact with two rings except a top disk and a bottom disk, wherein each ring is sandwiched between two disks, and wherein each ring is in contact with exactly two disks, wherein each ring has a diameter D o wherein each disk has a diameter D M that is larger than the diameter D o the periodic alternating structure alternating between the disks and the rings, the vibratory isolator providing a vibratory bandgap having a range of frequencies through which vibrations cannot pass, the range of frequencies lying between a rocking mode upper frequency and a shearing mode lower frequency, the rocking mode upper frequency being adjustable by adjusting a ratio of D m to D o , and the shearing mode lower frequency being adjustable by adjusting a ratio of a mass of at least one disk and a shear stiffness of at least one spring, the vibratory bandgap being bounded by an upper rocking mode frequency of approximately 85 Hertz (Hz), the vibratory bandgap being bounded by a lower shearing mode frequency of approximately 60 Hertz (Hz).