Impact mitigating membrane

The invention claimed is: 1. An impact mitigating membrane conformable to a surface of an object, comprising: a laminar core, comprising: a first lamina; a second lamina configured to shift relative to the first lamina, the second lamina coupled to the first lamina at a perimeter of an aperture defined in the laminar core; and a lubricating layer disposed between the first lamina and the second lamina and configured to reduce friction between the first lamina and the second lamina; a first encapsulating layer positioned adjacent the first lamina; a second encapsulating layer positioned adjacent the second lamina; and an anchoring attachment extending through the aperture in the laminar core and coupled to at least one of the first encapsulating layer or the second encapsulating layer, the anchoring attachment configured to constrain relative lateral motion between the laminar core and at least one of the first or second encapsulating layers, wherein the first encapsulating layer and the second encapsulating layer together surround the laminar core, and wherein the shift of the first lamina relative to the second lamina dissipates kinetic energy resulting from an impact force to the impact mitigating membrane. 2. The impact mitigating membrane of claim 1 , wherein the first lamina is coupled to the second lamina at a perimeter of the laminar core. 3. The impact mitigating membrane of claim 1 , wherein the lubricating layer is selected from the group consisting of a gas, a liquid, a solid, a colloid, a ferrofluid, and combinations thereof. 4. The impact mitigating membrane of claim 1 , wherein the first lamina and the second lamina are manufactured from elastic, stretchable, or rigid materials that are capable of elongation to a point of rupture when the impact force exceeds a threshold. 5. The impact mitigating membrane of claim 1 , wherein the coupling of the first lamina and the second lamina is selected from the group consisting of mechanical fasteners, chemical fasteners, adhesive, buttons, elastic bands, rivets, fusion, thread, hook and loop, radio frequency seal, ultrasonic weld, thermal impulse seal, and combinations thereof. 6. The impact mitigating membrane of claim 1 , wherein the anchoring attachment is selected from the group consisting of mechanical fasteners, chemical fasteners, elastic band, rivets, adhesive, buttons, fusion, thread, hook and loop, radio frequency seal, ultrasonic weld, thermal impulse seal, and combinations thereof. 7. The impact mitigating membrane of claim 6 , wherein the first lamina is coupled to the second lamina at a perimeter of the laminar core. 8. The impact mitigating membrane of claim 1 , wherein the first encapsulating layer is coupled to the first lamina by one or more fasteners selected from the group consisting of mechanical fasteners, chemical fasteners, adhesive, buttons, elastic bands, rivets, fusion, thread, hook and loop, radio frequency seal, ultrasonic weld, thermal impulse seal, and combinations thereof. 9. The impact mitigating membrane of claim 1 , wherein the second encapsulating layer is coupled to the second lamina by one or more fasteners selected from the group consisting of mechanical fasteners, chemical fasteners, adhesive, buttons, elastic bands, rivets, fusion, thread, hook and loop, radio frequency seal, ultrasonic weld, thermal impulse seal, and combinations thereof. 10. The impact mitigating membrane of claim 1 , wherein a fastener is used to define the coupling of the first lamina and the second lamina at the perimeter of the aperture. 11. The impact mitigating membrane of claim 1 , wherein more than one laminar core is enclosed within the first encapsulating layer and the second encapsulating layer. 12. The impact mitigating membrane of claim 1 , wherein the first encapsulating layer is integrated with the first lamina. 13. The impact mitigating membrane of claim 1 , wherein the second encapsulating layer is integrated with the second lamina. 14. The impact mitigating membrane of claim 1 , wherein the object is a protective equipment, the impact mitigating membrane further comprising a coupling feature configured to attach the impact mitigating membrane to the protective equipment. 15. The impact mitigating membrane of claim 1 , wherein a padded layer is integrated into at least one of the first or second encapsulating layers. 16. An impact mitigating membrane conformable to a surface of an object, comprising: a laminar core comprising: a first lamina; a second lamina coupled to the first lamina and configured to shift relative to the first lamina; and an aperture through the first lamina and the second lamina, the first lamina coupled to the second lamina at a perimeter of the aperture, the aperture configured to receive an anchoring attachment therethrough; a first encapsulating layer positioned adjacent the first lamina; a second encapsulating layer positioned adjacent the second lamina, the second encapsulating layer coupled to the first encapsulating layer through the anchoring attachment to constrain relative lateral motion between the laminar core and at least one of the first or second encapsulating layers, wherein the first encapsulating layer and the second encapsulating layer together surround the laminar core, and wherein the shift of the first lamina relative to the second lamina dissipates kinetic energy resulting from an impact force to the impact mitigating membrane, thereby reducing acceleration transferred to the object. 17. The impact mitigating membrane of claim 16 , further comprising a lubricating layer disposed between the first lamina and the second lamina configured to reduce friction between the first lamina and the second lamina, the lubricating layer selected from the group consisting of a gas, a liquid, a solid, a colloid, a ferrofluid, and combinations thereof. 18. An impact mitigating membrane conformable to a surface of an object, comprising: a laminar core, comprising: a first lamina; a second lamina configured to shift relative to the first lamina; and a lubricating layer disposed between the first lamina and the second lamina and configured to reduce friction between the first lamina and the second lamina; a first encapsulating layer positioned adjacent the first lamina; a second encapsulating layer positioned adjacent the second lamina; and a tether coupled to the laminar core and at least one of the first encapsulating layer or the second encapsulating layer, wherein an anchoring attachment extends through the tether and at least one of the first encapsulating layer or the second encapsulating layer, the tether configured to constrain relative lateral motion between the laminar core and at least one of the first or second encapsulating layers, wherein the first encapsulating layer and the second encapsulating layer together surround the laminar core, wherein the shift of the first lamina relative to the second lamina dissipates kinetic energy resulting from an impact force to the impact mitigating membrane, wherein the second lamina is coupled to the first lamina at a perimeter of an aperture defined in the laminar core, and wherein the tether passes through the aperture.