Blast/impact frequency tuning and mitigation

What is claimed is: 1. A tuning and mitigation system for mitigating a blast or impact event, said tuning and mitigation system comprising: an elastic layer; and a dissipative layer being made of a viscoelastic material having a critical damping frequency, said dissipative layer being proximate to said elastic layer, wherein the elastic layer and the dissipative layer are collectively configured to tune stress waves resulting from the blast or impact to one or more specific tuned frequencies that match the critical damping frequency of the dissipative layer such that densities and thicknesses of the elastic layer and of the dissipative layer are matched to an unrelaxed modulus, relaxed modulus, and critical frequency of the dissipative layer, the ratio of the relaxed to unrelaxed moduli of said dissipative layer being at least 10 so as to viscoelastically dissipate at least 80% of the kinetic energy of a plurality of cycles of the specific tuned frequency. 2. The tuning and mitigation system according to claim 1 wherein the elastic layer comprises two or more individual layers. 3. The tuning and mitigation system according to claim 1 wherein the dissipative layer comprises two or more individual layers. 4. The tuning and mitigation system according to claim 3 wherein a first of the two or more individual layers of the dissipative layer is configured to dissipate a first of said specific tuned frequencies and a second of the two or more individual layers of the dissipative layer is configured to dissipate a second of said specific tuned frequencies, said second specific tuned frequency being different than said first specific tuned frequency. 5. The tuning and mitigation system according to claim 3 wherein a first of the two or more individual layers of the dissipative layer is configured to dissipate a first of said specific tuned frequencies and a second of the two or more individual layers of the dissipative layer is configured to dissipate a second of said specific tuned frequencies, said second specific tuned frequency being the same as said first specific tuned frequency. 6. The tuning and mitigation system according to claim 1 wherein properties of said elastic layer are configured to tune stress waves resulting from the blast or impact to said specific tuned frequency using material parameters. 7. The tuning and mitigation system according to claim 6 wherein said properties are configured from the group consisting of thickness, material type, and bonding type. 8. The tuning and mitigation system according to claim 1 wherein said elastic layer is configured to allow passage of said specific tuned frequency to said dissipative layer, whereby said specific tuned frequency is dissipated in said dissipative layer. 9. The tuning and mitigation system according to claim 1 wherein said elastic layer is configured to allow passage of said specific tuned frequency to said dissipative layer, whereby said specific tuned frequency is viscoelastically dissipated in said dissipative layer. 10. The tuning and mitigation system according to claim 1 wherein a thickness of said dissipative layer is sufficient that the presence of a stress wave of said specific tuned frequency substantially decays before passage of said stress wave through said dissipative layer. 11. The tuning and mitigation system according to claim 1 wherein said elastic layer is joined to said dissipative layer.