Wireless downhole feedthrough system

What is claimed is: 1. In a flow completion system which includes a tubing spool positioned at the top of a wellbore and a tubing hanger landed in the tubing spool, the improvement comprising a system for communicating optical signals between an external device located outside the tubing spool and a downhole device located in the wellbore, the system comprising: a first wireless node which is positioned adjacent an outer surface portion of the tubing spool, the first wireless node being in communication with the external device via a fiber optic first cable; a second wireless node which is positioned in the tubing hanger generally opposite the first wireless node; the first and second wireless nodes being configured to communicate wirelessly through the tubing spool using near field magnetic induction (NFMI) communications; the tubing hanger comprising a feedthrough bore which extends generally axially from proximate the second wireless node to a bottom wall portion of the tubing hanger; a third wireless node which is positioned in the tubing hanger on a first side of the bottom wall portion; the second and third wireless node being connected by a second cable which is positioned in the feedthrough bore; a fourth wireless node which is positioned on a second side of the bottom wall portion generally opposite the third wireless node, the fourth wireless node being in communication with the downhole device via a fiber optic third cable; the third and fourth wireless nodes being configured to communicate wirelessly through the bottom wall portion using NFMI communications; a first optical converter which is configured to convert optical signals received from the external device over the first cable into corresponding signals for wireless transmission by the first wireless node through the tubing spool to the second wireless node; wherein the signals received by the second wireless node are transmitted over the second cable to the third wireless node for wireless transmission through the bottom wall portion to the fourth wireless node; and a second optical converter which is configured to convert the corresponding signals received by the fourth wireless node into optical signals for transmission over the third cable to the downhole device. 2. The flow completion system of claim 1 , wherein the second optical converter is configured to convert optical signals received from the downhole device over the third cable into corresponding signals for wireless transmission by the fourth wireless node to the third wireless node, wherein the signals received by the third wireless node are transmitted over the second cable to the second wireless node for wireless transmission to the first wireless node, and wherein the first optical converter is configured to covert the corresponding signals received by the first wireless node into optical signals for transmission over the first cable to the external device. 3. The flow completion system of claim 1 , wherein the second wireless node is positioned behind an outer diameter wall portion of the tubing hanger and the first and second wireless nodes are configured to communicate wirelessly through both the tubing spool and the outer diameter wall portion using NFMI communications. 4. An apparatus for communicating optical signals between an external device located on a first side of a wellbore barrier and a downhole device located on a second side of the wellbore barrier, the apparatus comprising: a first wireless node which is positioned on the first side of the wellbore barrier, the first wireless node being in communication with the external device via a first cable; a second wireless node which is positioned on the second side of the wellbore barrier, the second wireless node being in communication with the downhole device via a second cable; wherein the first and second wireless nodes are configured to communicate wirelessly through the wellbore barrier using near field magnetic induction (NFMI) communications; and wherein at least one of the first and second cables comprises a fiber optic cable and the apparatus further comprises a first optical converter which is configured to convert optical signals on the fiber optic cable into electrical signals for wireless transmission by the corresponding first or second wireless node through the wellbore barrier. 5. The apparatus of claim 4 , wherein each of the first and second cables comprises a respective fiber optic cable, the first optical converter is connected to the first cable and the apparatus further comprises a second optical converter which is configured to convert optical signals on the second cable into electrical signals for wireless transmission by the second wireless node. 6. The apparatus of claim 4 , wherein the wellbore barrier comprises a tubing spool, the first wireless node is positioned adjacent an outer surface portion of the tubing spool and the second wireless node is positioned adjacent an inner surface portion of the tubing spool generally opposite the first wireless node. 7. The apparatus of claim 4 , wherein the wellbore barrier comprises a tubing spool in which a tubing hanger is landed, the first wireless node is positioned adjacent an outer surface portion of the tubing spool and the second wireless node is positioned in the tubing hanger generally opposite the first wireless node. 8. The apparatus of claim 7 , wherein the second wireless node is positioned behind an outer diameter wall portion of the tubing hanger and the first and second wireless nodes are configured to communicate wirelessly through both the tubing spool and the outer diameter wall portion using NFMI communications. 9. The apparatus of claim 7 , wherein the second wireless node is connected to a fiber optic third cable which is positioned in an axial feedthrough bore in the tubing hanger and is connected to the second cable with a dry mate connector that is mounted to the tubing hanger. 10. The apparatus of claim 4 , wherein the wellbore barrier comprises a wellhead, the first wireless node is positioned adjacent an outer surface portion of the wellhead and the second wireless node is located inside the wellhead generally opposite the first wireless node. 11. The apparatus of claim 10 , wherein the wellbore barrier further comprises a christmas tree which is connected to the top of the wellhead by a tree connector, and wherein the first wireless node is mounted to the tree connector. 12. The apparatus of claim 10 , wherein an isolation sleeve extends from the christmas tree into the wellhead and the second wireless node is mounted to an inside surface portion of the isolation sleeve. 13. An apparatus for communicating signals wirelessly across a wellbore barrier defined by a tubing spool which is positioned at the top of a well bore and a tubing hanger which is landed in the tubing spool, the apparatus comprising: a first wireless node which is positioned adjacent an outer surface portion of the tubing spool, the first wireless node being in communication with an external device; and a second wireless node which is positioned in the tubing hanger generally opposite the first wireless node, the second wireless node being in communication with a downhole device via a second cable which is positioned in an axial feedthrough bore in the tubing hanger; wherein the first and second wireless nodes are configured to communicate wirelessly through the tubing spool using near field magnetic induction (NFMI) communications. 14. The apparatus of claim 13 , wherein the second wireless node is positioned behind an outer diameter wall portion of the tubing hanger an