Handheld mobile device with hidden antenna formed of metal injection molded substrate

The invention claimed is: 1. A housing of a handheld mobile device, the housing comprising: a ceramic layer forming a continuous outermost surface of the handheld mobile device; and an antenna layer underlying the ceramic layer, the antenna layer having a contiguous surface that spans the ceramic layer and includes: a plurality of conductive elements formed from a metal injection molded (MIM) substrate; and an antenna break of non-conductive material formed across a backside of the handheld mobile device to electrically separate the plurality of conductive elements and collectively form an antenna of the handheld mobile device that is hidden by the ceramic layer from an exterior view of the handheld mobile device. 2. The housing of claim 1 , wherein the ceramic layer is a metal oxide layer formed from the MIM substrate. 3. The housing of claim 2 , wherein the metal oxide layer is formed by plasma electrolytic oxidation of the MIM substrate. 4. The housing of claim 2 , wherein the plurality of conductive elements are physically separated by a gap in the MIM substrate. 5. The housing of claim 4 , wherein the gap is formed in the MIM substrate in part by an initial mechanical etching process. 6. The housing of claim 5 , wherein the gap is formed to completion in the MIM substrate in part by an electrochemical process after the initial mechanical etching process has completed. 7. The housing of claim 5 , wherein the mechanical etching process is a computer numerical control mechanical machining process. 8. The housing of claim 4 , wherein the gap is the antenna break backfilled with a non-conductive material. 9. The housing of claim 8 , wherein the non-conductive material is an adhesive that bonds the ceramic layer and the plurality of conductive elements. 10. The housing of claim 8 , further comprising: an insulating layer that coats a surface of each conductive elements with a non-conductive material such that the plurality of conductive elements are electrically insulated from each other by the antenna break, the ceramic layer, and the insulating layer. 11. The housing of claim 1 , wherein the MIM substrate comprises any of titanium, aluminum, magnesium, or a metal alloy. 12. The housing of claim 1 , wherein the handheld mobile device is a smartphone and the antenna is embedded in a case forming the housing of the smartphone. 13. A smartphone device comprising: a case forming a housing of the smartphone device, the case including: a continuous outermost surface of the case; and a contiguous antenna structure that underlies and spans the continuous outermost surface of the smartphone device such that the antenna structure is hidden from an exterior view of the smartphone device by the continuous outermost surface of the smartphone device, the antenna structure including: a plurality of conductive elements formed of a metal injection molded (MIM) substrate; and an antenna break of non-conductive material formed across a backside of the smartphone device to separate the plurality of conductive elements and collectively form the antenna of the smartphone device. 14. The smartphone device of claim 13 , wherein the continuous outermost surface is a surface of a metal oxide coating formed by plasma electrolytic oxidation of the MIM substrate. 15. The smartphone device of claim 13 , wherein the plurality of conductive elements are electrically separated by a gap in the MIM substrate formed in part by an initial mechanical etching process and etched to completion by a subsequent electrochemical process. 16. The smartphone device of claim 15 , wherein the mechanical etching is a computer numerical control mechanical machining. 17. The smartphone device of claim 15 , wherein the gap is the antenna break backfilled with the non-conductive material. 18. The smartphone device of claim 17 , wherein the non-conductive material is an adhesive that bonds the metal oxide coating and the plurality of conductive elements. 19. The smartphone device of claim 13 , further comprising: an insulating layer that coats a surface of each conductive element with the non-conductive material such that the plurality of conductive elements are electrically insulated from each other by the antenna break, the metal oxide coating, and the insulating layer.