Temperature independent physically unclonable function device

The invention claimed is: 1. A physically unclonable function (PUF) device comprising: a plurality of conductors arranged such that each of the plurality of conductors interacts electrically, magnetically, or both, with at least one other of the plurality of conductors; a media surrounding at least a portion of each of the conductors, wherein the media includes a plurality of temperature compensation particles arranged throughout a volume of the media such that a permittivity of the media, a permeability of the media, or both, is temperature independent; and interface circuitry for applying an electrical challenge signal to at least one of the plurality of conductors and for receiving an electrical output signal in response to the electrical challenge signal from at least one separate conductor such that the electrical output signal is unique to the PUF device. 2. The PUF device of claim 1 , wherein each of the plurality of temperature compensation particles comprises at least two different materials. 3. The PUF device of claim 2 , wherein the at least two different materials includes at least a first material and a second material, wherein a first permittivity temperature coefficient of the first material has an opposite sign to a second permittivity temperature coefficient of the second material, a first permeability temperature coefficient of the first material has an opposite sign to a second permeability temperature coefficient of the second material, or both. 4. The PUF device of claim 2 , wherein the at least two different materials of each temperature compensation particle are sintered together. 5. The PUF device of claim 1 , wherein the plurality of temperature compensation particles are micro-particles, nano-particles, or both. 6. The PUF device of claim 1 , wherein the plurality of conductors are at least one of electrically insulated wires overlapping one another, embedded within a substrate material with vias to allow for overlapping routing, and formed from a complex media of mixed permittivity, permeability, and conductivity. 7. The PUF device of claim 1 , wherein the interface circuitry is configured to apply the electrical challenge signal to a varying selection of the plurality of conductors, receive the electrical output signal on a varying selection of the plurality of conductors, or both. 8. The PUF device of claim 1 , wherein the interface circuitry is arranged to vary a number of conductors to which the electrical challenge signal is applied, vary a number of conductors from which the response is received after each challenge is applied, or both. 9. The PUF device of claim 1 , wherein the interface circuitry is arranged to apply at least a second electrical challenge signal to at least one of the plurality of conductors and to receive at least a second electrical output from a different one of the plurality of conductors to generate an identifying response to the electrical challenge signal that is unique to the PUF device. 10. The PUF device of claim 9 , wherein the electrical challenge signal is a first electrical challenge signal, and wherein the second electrical challenge signal is applied to a different set of the plurality of conductors than the first electrical challenge signal. 11. The PUF device of claim 9 , wherein the second electrical output is received from a different set of the plurality of conductors than a first electrical output. 12. A method of fabricating temperature compensation particles arranged in a media that surrounds a plurality of conductors of a PUF device such that a permittivity and/or a permeability of the media is substantially temperature independent, the method comprising: forming a composite material by combining at least two different materials, the composite material having a temperature coefficient selected such that the permittivity and/or the permeability of the composite material is substantially temperature independent; and grinding the composite material into particles. 13. The method of claim 12 , wherein a first permittivity temperature coefficient or a first permeability temperature coefficient of a first material of the at least two different materials has an opposite sign to a second permittivity temperature coefficient or a second permeability temperature coefficient of a second material of the at least two different materials. 14. The method of claim 12 , wherein combining a first material and a second material comprises at least one of: bonding the first material to the second material; welding the first material to the second material; fusing the first material to the second material; growing the second material on the first material; or depositing the second material on to the first material.