Systems and methods for high capacity power delivery to remote nodes

What is claimed is: 1. A network interface device, the network interface device comprising: a first hybrid power-data port; a second hybrid power-data port; a managed gated pass-through power bus coupled between the first hybrid power-data port and the second hybrid power-data port; and a node controller configured to switch to being powered from either one of the first hybrid power-data port or the second hybrid power-data port, wherein power flow though the managed gated pass-through power bus is controlled by the node controller; wherein the node controller is configured to switch a direction of power flow through the managed gated pass-through power bus between the first hybrid power-data port and the second hybrid power-data port. 2. The network interface device of claim 1 , wherein the first hybrid power-data port and the second hybrid power-data port are configured to couple with a hybrid power-data cable comprising either: at least one pair of electrical conductors to transport electric power, and a plurality of optical fibres to transport data communications, or at least one pair of electrical conductors to transport electric power, and a plurality of electrical conductors to transport data communications. 3. The network interface device of claim 1 , further comprising: a local power bus coupled to at least a first local port, wherein the local power bus operates at a different voltage than the managed gated pass-through power bus, wherein the first local port is configured to deliver electric power and a data connectivity to a remote powered device coupled to the first local port; and a DC-to-DC converter, wherein power flow from the managed gated pass-through power bus to the local power bus is controlled by the DC-to-DC converter. 4. The network interface device of claim 3 , wherein the DC-to-DC converter is coupled to a managed gated pass-through power bus via a third hybrid power-data port that branches from the managed gated pass-through power bus. 5. The network interface device of claim 3 , wherein the first local port comprises a Power-over-Ethernet IEEE 802.3x standard compliant port. 6. The network interface device of claim 3 , wherein the local power bus operates at a lower voltage than the managed gated pass-through power bus. 7. The network interface device of claim 3 , further comprising: an internal or external local energy storage and management device that includes at least one energy storage device configured to provide power to the local power bus. 8. The network interface device of claim 7 , further comprising: at least one renewable energy device configured to provide power to the local power bus. 9. The network interface device of claim 7 , wherein the DC-to-DC converter comprises a bi-directional DC-to-DC converter; wherein the node controller is configured to control the bi-directional DC-to-DC converter to direct power flow from the internal local energy storage and management device to the managed gated pass: through power bus. 10. The network interface device of claim 1 , further comprising: a first port controller coupled to the first hybrid power-data port, wherein the first port controller is configured to harvest energy from a polling signal received over the first hybrid power-data port. 11. The network interface device of claim 10 , wherein the first port controller is configured to transmit a response to the polling signal, wherein the response to the polling signal includes power classification information regarding the network interface device. 12. The network interface device of claim 10 , wherein the polling signal comprises one or more of a low frequency AC polling signal, an on-off keying polling signal, an amplitude modulation polling signal, a phase-shift keying (psk) polling signal, a frequency-shift keying (fsk) polling signal, or a dual-tone multi-frequency polling signal. 13. The network interface device of claim 1 , further comprising: a third hybrid power-data port coupled to the managed gated pass-through power bus; wherein the node controller controls power flow through the third hybrid power-data port by controlling the managed gated pass-through power bus. 14. The network interface device of claim 1 , further comprising: a disconnect mechanism coupled to first port controller and the first hybrid power-data port, wherein the disconnect mechanism includes a mechanical interlock that secures a hybrid power-data cable to the hybrid power-data port; wherein when the disconnect mechanism is actuated, the disconnect mechanism sends a signal to the node controller to curtail current demand through the first hybrid power-data port before the mechanical interlock releases the hybrid power-data cable. 15. A power-up method for managing power distribution to remote delivery nodes of a power distributing fiber access network, the method comprising: transmitting a polling signal from an un-powered first hybrid power-data port of a power sourcing equipment device; when a response to the polling signal is received at the first hybrid power-data port from a remote distribution node, initiate a power-up handshake with the remote distribution node; sending power class information for the remote distribution node received during the power-up handshake to a power management system coupled to the power sourcing equipment device; and in response to an authorization received from the power management system based on the power class information: enabling power delivery from the first hybrid power-data port to a hybrid power-data cable coupled to the first hybrid power-data port, and switching a direction of power flow within a managed gated pass-through power bus of the remote distribution node between the first hybrid power-data port and a second hybrid power-data port to reverse powering of the remote distribution node from the first hybrid power-data port of the power sourcing equipment device to the second hybrid power-data port of the power sourcing equipment device. 16. The method of claim 15 , further comprising: controlling at least one external port of the remote distribution node with the power management system. 17. The method of claim 15 , further comprising: controlling at least one internal port within the remote distribution node with the power management system. 18. The method of claim 17 , wherein the at least one internal port of within the remote distribution node controls power flow between a first bus operating at a first voltage level and a second but operating at a second voltage level different than the first voltage level, wherein power is delivered from the first hybrid power-data port to the hybrid power-data cable at the first voltage level.