Dual mode cooling system for use with in-wall video-codec and other electronic circuits

What is claimed is: 1. A dual mode cooling system, comprising: electronic heat generating circuitry; a printed circuit board upon which the electronic heat generating circuitry is located on a first side; a substantially adiabatic enclosure adapted to house the electronic heat generating circuitry, printed circuit board and other components of the dual mode cooling system; a finned heat sink adapted to be in thermal contact with the electronic heat generating circuitry, the finned heat sink comprising a plurality of heat radiating fins; a faceplate adapted to enclose the substantially adiabatic enclosure and seal the substantially adiabatic enclosure against an interior wall, and wherein the faceplate comprises— a cool air intake port adapted to receive cool air from an area external to the substantially adiabatic enclosure and provide the cool air to an interior portion of the substantially adiabatic enclosure, and a heated air exhaust port adapted to exhaust heated air out of the substantially adiabatic enclosure into an area external to the substantially adiabatic enclosure; a fan; an active cooling path, comprising: a path of air that passes through the cool air intake port through the fan, through the plurality of heat radiating fins, and through the heated air exhaust port; and a passive cooling path, comprising: a conductive heat transfer path adapted to transfer heat from the electronic heat generating circuitry through one or more heat conducting devices, to the faceplate, wherein heat received by the faceplate is convectively transferred to a volume of air surrounding the faceplate. 2. The dual mode cooling system according to claim 1 , wherein the heated air exhaust port is cater cornered with respect to the cool air intake port. 3. The dual mode cooling system according to claim 1 , wherein the combination of the passive cooling paths and active cooling path is adapted to remove substantially all heat generated by the electronic heat generating circuitry from the substantially adiabatic enclosure into an area within which the substantially adiabatic enclosure is located. 4. The dual mode cooling system according to claim 1 , wherein the combination of the passive cooling paths is adapted to transfer heat to and through the faceplate in such a manner that following the electronic heat generating circuitry being put into an inactive state and the fan being shut off, the combination of the passive cooling paths convectively transfers heat away from the interior of the substantially adiabatic enclosure through the faceplate such that the faceplate remains at a temperature below an unsafe temperature. 5. The dual mode cooling system according to claim 4 , wherein the convective transfer of heat away from the faceplate and interior of the substantially adiabatic enclosure is such that the faceplate remains at a temperature below an unsafe temperature occurs through the conductive transfer of heat to a first area of the faceplate. 6. The dual mode cooling system according to claim 5 , wherein the unsafe temperature is about 70° C. 7. The dual mode cooling system according to claim 1 , further comprising: a baffle wall that separates an interior of the substantially adiabatic enclosure into a cool air baffle zone and a heated air baffle zone, such that substantially only cool air is located in the cool air baffle zone and substantially only heated air is located in the heated air baffle zone. 8. The dual mode cooling system according to claim 7 , further comprising: at least one or more holes in the printed circuit board that allow cool air to flow from one side of the printed circuit board to the other side of the printed circuit board in the cool air baffle zone; and at least one or more holes in the printed circuit board that allow heated air to flow from one side of the printed circuit board to the other side of the printed circuit board in the heated air baffle zone. 9. The dual mode cooling system according to claim 1 , wherein the faceplate comprises: at least one audio video signal connector. 10. The dual mode cooling system according to claim 1 , wherein the electronic heat generating circuitry comprises: audio-video processing circuitry. 11. The dual mode cooling system according to claim 1 , wherein the substantially adiabatic enclosure comprises: a standard gang box. 12. The dual mode cooling system according to claim 11 , wherein the standard gang box can be located within an insulated wall. 13. The dual mode cooling system according to claim 1 , further comprising: one or more through hole thermal vias located in the printed circuit board that are each adapted to be in thermal contact with the electronic heat generating circuitry and to accept heat generated by the electronic heat generating circuitry and to transfer the same to the finned heat sink, the finned heat sink located on a second side of the printed circuit board. 14. The dual mode cooling system according to claim 1 , wherein the cool air intake port comprises— one or more holes in the faceplate formed at an angle α with respect to a first imaginary line that is formed perpendicular to an outer surface of the faceplate, such that the cool intake air is ingested into the substantially adiabatic enclosure from a first direction, and wherein the heated air exhaust port comprises— one or more holes in the faceplate formed at an angle β with respect to a second imaginary line that is formed perpendicular to the outer surface of the faceplate such that the heated exhaust air is expelled away from the faceplate in a second direction. 15. The dual mode cooling system according to claim 14 , wherein the angle α and the angle β are each about 0°. 16. The dual mode cooling system according to claim 14 , wherein the angle α is an acute angle and the angle β is about 0°. 17. The dual mode cooling system according to claim 14 , wherein the cool air intake port formed at the angle α points away from the heated air exhaust port formed at the angle β. 18. The dual mode cooling system according to claim 14 , wherein the angle α is about 0° and the angle β is an acute angle. 19. The dual mode cooling system according to claim 14 , wherein the angle α is an acute angle and the angle β is an acute angle. 20. An audio-video distribution system, comprising: an audio-video encoder adapted to receive at least one high definition multimedia interface (HDMI) encoded audio-video (AV) signal via an HDMI cable, encode the same as an AV-over-internet protocol (AV-over-IP) signal, transmit the AV-over-IP signal to an AV receiver/splitter, wherein the AV receiver/splitter is adapted to receive the AV-over-IP signal, split the audio portion from the video portion of the AV-over-IP signal, convert the video portion back to an HDMI encoded video signal, re-transmit the HDMI encoded video signal to a display that is adapted to display an HDMI encoded video signal, and re-transmit the audio portion to one or more loudspeakers, and wherein the audio-video encoder comprises— electronic heat generating circuitry; a printed circuit board upon which the electronic heat generating circuitry is located on a first side; a substantially adiabatic enclosure adapted to house the electronic heat generating circuitry, printed circuit board and other components of the dual mode cooling system; a finned heat sink adapted to be in thermal contact with the electronic heat generating circuitry, the finned heat sink comprisin