Power over data lines system with redundant power connections

What is claimed is: 1. A powered data communications system comprising: a master device having a first port and a second port, the master device being configured to apply a DC voltage from a voltage source to the first port; a plurality of slave devices, each slave device having a third port and a fourth port; conductors serially connecting the slave devices, via their third port and fourth port, to the master device in a ring between the first port and the second port of the master device, wherein a first end slave device is coupled to the first port of the master device, and a second end slave device is coupled to the second port of the master device, the conductors being configured to simultaneously carry the DC voltage and data; the plurality of slave devices being configured to be sequentially powered up, starting with the first end slave device and ending with the second end slave device, by sequentially applying the DC voltage to an adjacent downstream slave device in a first direction around the ring by closing switches in the slave devices; the slave devices and the master device being configured to perform a detection routine on the adjacent downstream slave device prior to applying the DC voltage to the adjacent downstream slave device; and wherein the master device is configured to detect whether the DC voltage has been sequentially applied to all the slave devices by detecting a presence of the DC voltage at the second port of the master device and, if the master does not detect the presence of the DC voltage at the second port, the master device is configured to apply the DC voltage to both the first port and the second port to sequentially power up the slave devices in both the first direction and a second direction around the ring of the slave devices. 2. The system of claim 1 wherein the slave devices are configured to perform the detection routine by detecting a presence of a signature impedance in the adjacent downstream slave device and then applying the DC voltage to the adjacent downstream device. 3. The system of claim 1 wherein the master device comprises a first switch coupled to the first port for connecting the DC voltage to the conductors coupled to the first port, and comprises a second switch coupled to the second port for connecting the DC voltage to the conductors coupled to the second port. 4. The system of claim 3 wherein the master device comprises a master controller configured to control opening and closing of the first switch and the second switch to apply the DC voltage to the first port and second port, respectively. 5. The system of claim 3 wherein the slave devices comprise a third switch coupled to the third port for coupling the DC voltage to the associated slave device to power up the associated slave device, wherein the slave devices further comprise a fourth switch coupled to the fourth port for coupling the DC voltage to the conductors for powering up a downstream slave device. 6. The system of claim 5 wherein the slave devices comprise a slave controller configured to control opening and closing of the third switch and fourth switch to conduct the DC voltage to and from the associated slave device. 7. The system of claim 1 wherein the DC voltage is coupled to the conductors via inductors. 8. The system of claim 1 wherein each of the slave devices comprises a physical layer device (PHY) for receiving differential data on the conductors via AC coupling components. 9. The system of claim 1 wherein the conductors comprise a twisted wire pair that carry both the DC voltage and differential data. 10. The system of claim 1 wherein the system is a Power over Data Lines (PoDL) system. 11. The system of claim 1 wherein the system is a Power over Ethernet (PoE) system. 12. A method performed by a powered data communications system comprising: providing a DC voltage, by a master device, to a first port of the master device, the master device also having a second port; wherein a plurality of slave devices, each slave device having a third port and a fourth port, are connected serially between the first port and the second port in a ring via conductors configured to simultaneously carry the DC voltage and data, wherein a first end slave device is coupled to the first port of the master device, and a second end slave device is coupled to the second port of the master device; sequentially powering up the plurality of slave devices, starting with the first end slave device and ending with the second end slave device, by sequentially applying the DC voltage to the adjacent downstream slave device in a first direction around the ring by closing switches in the slave devices; performing a detection routine on the adjacent downstream slave device prior to applying the DC voltage to the adjacent downstream slave device in the first direction around the ring; detecting, by the master device, whether the DC voltage has been sequentially applied to all the slave devices by detecting a presence of the DC voltage at the second port of the master device; and if the master does not detect the presence of the DC voltage at the second port, applying, by the master device, the DC voltage to both the first port and the second port to sequentially power up the slave devices in both the first direction and a second direction around the ring of the slave devices. 13. A powered data communications system comprising: a first master device having a first port, the first master device being configured to provide a DC voltage and apply the DC voltage to the first port; a second master device having a second port, the second master device being configured to provide the DC voltage and apply the DC voltage to the second port; a plurality of slave devices connected serially between the first master device and the second master device, each slave device having a third port and a fourth port; conductors serially connecting the slave devices, via their third port and fourth port, between the first port of the first master device and the second port of the second master device, wherein a first end slave device is coupled to the first port of the first master device, and a second end slave device is coupled to the second port of the second master device, the conductors being configured to simultaneously carry the DC voltage and data; the plurality of slave devices being configured to be sequentially powered up, starting with the first end slave device and ending with the second end slave device, by sequentially applying the DC voltage to an adjacent downstream slave device in a first direction by closing switches in the slave devices; and wherein the second master device is configured to detect whether the DC voltage has been sequentially applied to all the slave devices by detecting a presence of the DC voltage at the second port of the second master device and, if the second master does not detect the presence of the DC voltage at the second port, the second master device is configured to apply the DC voltage to the second port to sequentially power up the slave devices in a second direction. 14. The system of claim 13 wherein the slave devices and the first master device are configured to perform a detection routine on an adjacent downstream slave device prior to applying the DC voltage to the adjacent downstream slave device. 15. The system of claim 13 wherein the first master device comprises a first switch coupled to the first port for connecting the DC voltage to the conductors coupled to the first port, and the second master device comprises a second switch coupled to the second port for co