Abstract: A Power over Data Lines (PoDL) system provides a DC voltage and differential data signals on the same wire pair. A Powered Device (PD) load is coupled to the wire pair, via a gyrator, for being powered by the DC voltage. The gyrator emulates the DC-coupling properties of inductors using active components. The gyrator includes transistors that are controlled to act as a full-bridge rectifier for ensuring a correct polarity DC voltage is applied to the PD load. Since the transistors operate in saturation and are coupled to be insensitive to differential data signals on the wire pair, the current supplied to the PD load is substantially unaffected by the differential data signals. Negative feedback circuits in the gyrator reduce fluctuations in current through the gyrator due to differential data signals on the wire pair. No inductors are required in the gyrator. A PHY is AC-coupled to the wire pair via capacitors.

Abstract: In a Power over Data Lines (PoDL) system that conducts differential data and DC power over the same wire pair, various DC coupling techniques are described that improve DC voltage coupling while attenuating AC common mode noise and avoiding mode conversion. A first CMC and AC coupling capacitors are connected in series between a PHY and a twisted wire pair. A DC power supply is DC coupled to the wires via a series connection of a DMC and either matched inductors or a second CMC. Coupled between the DMC and the inductors/CMC is an RC termination circuit comprising a first capacitor coupled to one leg and a matched second capacitor coupled to the other leg. The two capacitors are connected to the same resistor coupled to ground.

Abstract: A PoDL system uses a gyrator for DC coupling of DC power from a PSE to a wire pair, and/or decoupling DC power from a wire pair for a PD. The gyrators obviate the use of discrete inductors for DC-coupling/decoupling and can be formed as an integrated circuit. The gyrators use a small integrated capacitor and invert and multiply the capacitor effect to emulate an inductor. The gyrators present a high impedance to AC current and a low impedance to DC current. Various gyrator designs, such as positive and negative polarity gyrators, and configurations are disclosed. Gyrators are described with analog current limit and power switch control, so multiple functions are integrated on the same IC chip.

Abstract: A Power over Data Lines (PoDL) system provides a DC voltage and differential data signals on the same wire pair. A Powered Device (PD) load is coupled to the wire pair, via a gyrator, for being powered by the DC voltage. The gyrator emulates the DC-coupling properties of inductors using active components. The gyrator includes transistors that are controlled to act as a full-bridge rectifier for ensuring a correct polarity DC voltage is applied to the PD load. Since the transistors operate in saturation and are coupled to be insensitive to differential data signals on the wire pair, the current supplied to the PD load is substantially unaffected by the differential data signals. Negative feedback circuits in the gyrator reduce fluctuations in current through the gyrator due to differential data signals on the wire pair. No inductors are required in the gyrator. A PHY is AC-coupled to the wire pair via capacitors.

Abstract: A PoDL system uses a gyrator for DC coupling of DC power from a PSE to a wire pair, and/or decoupling DC power from a wire pair for a PD. The gyrators obviate the use of discrete inductors for DC-coupling/decoupling and can be formed as an integrated circuit. The gyrators use a small integrated capacitor and invert and multiply the capacitor effect to emulate an inductor. The gyrators present a high impedance to AC current and a low impedance to DC current. Various gyrator designs, such as positive and negative polarity gyrators, and configurations are disclosed. Gyrators are described with analog current limit and power switch control, so multiple functions are integrated on the same IC chip.

Abstract: In an Intrinsically Safe (IS) PoDL/PoE system, a PHY in power sourcing equipment (PSE) has its differential transmit terminals coupled across a primary winding of an isolation transformer. One secondary winding is coupled between a positive terminal of a DC voltage source and a first wire of a twisted wire pair. Another secondary winding is coupled between a negative terminal (e.g., ground) of the DC voltage source and a second wire of the twisted wire pair. The secondary windings provide differential data signals output from the PHY's transceiver to the wire pair, while the DC voltage from the DC voltage source is coupled to the wire pair via the two secondary windings. The DC power is applied to a remote power device having a PHY that communicates with the PSE PHY. Therefore, the secondary windings have the dual purpose of DC-coupling and magnetically coupling the differential data to/from the PHY.

Abstract: In an Intrinsically Safe (IS) PoDL/PoE system, a PHY in power sourcing equipment (PSE) has its differential transmit terminals coupled across a primary winding of an isolation transformer. One secondary winding is coupled between a positive terminal of a DC voltage source and a first wire of a twisted wire pair. Another secondary winding is coupled between a negative terminal (e.g., ground) of the DC voltage source and a second wire of the twisted wire pair. The secondary windings provide differential data signals output from the PHY's transceiver to the wire pair, while the DC voltage from the DC voltage source is coupled to the wire pair via the two secondary windings. The DC power is applied to a remote power device having a PHY that communicates with the PSE PHY. Therefore, the secondary windings have the dual purpose of DC-coupling and magnetically coupling the differential data to/from the PHY.

Abstract: In a PoE system, DC power is transmitted over two wire pairs. The primary winding of an isolation transformer is connected across the differential I/O terminals of a first PHY (a transceiver). A positive voltage output of a power supply is connected to a center tap of the secondary winding, and the secondary winding is coupled across a first wire pair. In this way, differential data and DC power is supplied to the first wire pair. A CMC is connected between the secondary winding and an autotransformer which is also connected across the first wire pair. A center tap of the autotransformer is also connected to the positive voltage output of the power supply, so that the current to the powered device is shared by the isolation transformer and the autotransformer. A similar circuit, with a second PHY, is used for the DC power return path.

Abstract: A PoDL system conducts differential data and DC power over the same wire pair, and various DC coupling techniques are described that improve DC voltage coupling while attenuating AC common mode noise. Pairs of differential mode chokes (DMCs) are used to share current supplied by a power supply. In one embodiment, one DMC is coupled to the line side of a common mode choke (CMC), and one DMC is coupled to the PHY side of the CMC. The line-side DMC has windings that are loosely magnetically coupled so that DMC does not present a very low impedance to AC common mode noise on the wires. Therefore, the performance of the wires' RC termination circuitry is not adversely affected by the line-side DMC when minimizing reflections of common mode signals. The DMCs may use the same magnetic core, and the CMC may be series CMCs that used the same magnetic core.

Abstract: In a PoE system, DC power is transmitted over two wire pairs. The primary winding of an isolation transformer is connected across the differential I/O terminals of a first PHY (a transceiver). A positive voltage output of a power supply is connected to a center tap of the secondary winding, and the secondary winding is coupled across a first wire pair. In this way, differential data and DC power is supplied to the first wire pair. A CMC is connected between the secondary winding and an autotransformer which is also connected across the first wire pair. A center tap of the autotransformer is also connected to the positive voltage output of the power supply, so that the current to the powered device is shared by the isolation transformer and the autotransformer. A similar circuit, with a second PHY, is used for the DC power return path.

Abstract: In a PoDL system, where DC power and differential data are supplied over the same conductors between a PSE and a PD, a low-power test is first performed to determine the conductor resistance. The PSE and PD are connected to the conductors via DC-coupling inductors that block the data signals. Such inductors have a DC resistance (DCR). To avoid the DCR of the PD inductors being included in the resistance test of the conductors and to avoid the requirement of additional pins for kelvin sensing, the PD includes a MOSFET switch connected across the conductors on the line-side of the PD inductors. The PSE applies a current pulse of a known value to one of the conductors while the MOSFET switch is temporarily closed. The PSE measures the resulting voltage across the wires and uses Ohm's law to more accurately calculate the resistance of the conductors.

Abstract: In a Power over Data Lines (PoDL) system that conducts differential data and DC power over the same wire pair, various DC coupling techniques are described that improve DC voltage coupling while attenuating AC common mode noise. Pairs of differential mode chokes (DMCs) are used to share current supplied by a single phase or multi-phase power supply. In one embodiment, one DMC is coupled to the line side of a common mode choke (CMC), and one DMC is coupled to the PHY side of the CMC. The line-side DMC has windings that are loosely magnetically coupled so that DMC does not present a very low impedance to AC common mode noise on the wires. Therefore, the performance of the wires' RC termination circuitry is not adversely affected by the line-side DMC when minimizing reflections of common mode signals.

Abstract: In a PoDL system, a PHY has its I/O terminals coupled to a wire pair via a galvanic isolation transformer and a CMC. Thus, DC power and common mode noise are blocked from the PHY inputs. One end of the secondary winding of the transformer is directly coupled to one winding of the CMC. A DC power supply has its positive voltage terminal directly coupled to the other end of the secondary winding and has its other output terminal (e.g., ground) directly coupled to the other winding of the CMC. An AC-coupling capacitor is coupled between the two outputs of the power supply. Differential signals are applied across the secondary winding to couple the differential signals to the PHY, while the secondary winding conducts the DC voltage to one of the wires (via the CMC), and the ground is coupled to the other one of the wires (via the CMC).

Abstract: In a Power over Data Lines (PoDL) system that conducts differential data and DC power over the same wire pair, various DC coupling techniques are described that improve DC voltage coupling while attenuating AC common mode noise and avoiding mode conversion. A first CMC and AC coupling capacitors are connected in series between a PHY and a twisted wire pair. A DC power supply is DC coupled to the wires via a series connection of a DMC and either matched inductors or a second CMC. Coupled between the DMC and the inductors/CMC is an RC termination circuit comprising a first capacitor coupled to one leg and a matched second capacitor coupled to the other leg. The two capacitors are connected to the same resistor coupled to ground.

Abstract: A PoDL system conducts differential data and DC power over the same wire pair, and various DC coupling techniques are described that improve DC voltage coupling while attenuating AC common mode noise. Pairs of differential mode chokes (DMCs) are used to share current supplied by a power supply. In one embodiment, one DMC is coupled to the line side of a common mode choke (CMC), and one DMC is coupled to the PHY side of the CMC. The line-side DMC has windings that are loosely magnetically coupled so that DMC does not present a very low impedance to AC common mode noise on the wires. Therefore, the performance of the wires' RC termination circuitry is not adversely affected by the line-side DMC when minimizing reflections of common mode signals. The DMCs may use the same magnetic core, and the CMC may be series CMCs that used the same magnetic core.

Abstract: In a Power over Data Lines (PoDL) system that conducts differential data and DC power over the same wire pair, various DC coupling techniques are described that improve DC voltage coupling while attenuating AC common mode noise. Pairs of differential mode chokes (DMCs) are used to share current supplied by a single phase or multi-phase power supply. In one embodiment, one DMC is coupled to the line side of a common mode choke (CMC), and one DMC is coupled to the PHY side of the CMC. The line-side DMC has windings that are loosely magnetically coupled so that DMC does not present a very low impedance to AC common mode noise on the wires. Therefore, the performance of the wires' RC termination circuitry is not adversely affected by the line-side DMC when minimizing reflections of common mode signals.

Abstract: A PHY is coupled across a primary winding of an isolation transformer for differential data transmission and reception between PHYs and for DC isolation. Positive and negative low impedance terminals of a DC power supply are coupled to first and second secondary windings of the transformer as split center taps of the transformer. Respective ends of the wires in the wire pair are coupled to the other ends of the secondary windings. Therefore, the power supply conducts DC current through the secondary windings, while the differential data signals also flow through the secondary windings, generating corresponding differential data signals at the inputs to the PHY. The transformer also attenuates common mode noise. Therefore, the circuit makes multi-use of the isolation transformer, allowing fewer components to be used for the DC coupling, wire termination, and common mode noise cancellation.

Abstract: A PHY is coupled across a primary winding of an isolation transformer for differential data transmission and reception between PHYs and for DC isolation. Positive and negative low impedance terminals of a DC power supply are coupled to first and second secondary windings of the transformer as split center taps of the transformer. Respective ends of the wires in the wire pair are coupled to the other ends of the secondary windings. Therefore, the power supply conducts DC current through the secondary windings, while the differential data signals also flow through the secondary windings, generating corresponding differential data signals at the inputs to the PHY. The transformer also attenuates common mode noise. Therefore, the circuit makes multi-use of the isolation transformer, allowing fewer components to be used for the DC coupling, wire termination, and common mode noise cancellation.

Abstract: A PHY is coupled across a primary winding of an isolation transformer for differential data transmission and reception between PHYs and for DC isolation. Positive and negative low impedance terminals of a DC power supply are coupled to first and second secondary windings of the transformer as split center taps of the transformer. Respective ends of the wires in the wire pair are coupled to the other ends of the secondary windings. Therefore, the power supply conducts DC current through the secondary windings, while the differential data signals also flow through the secondary windings, generating corresponding differential data signals at the inputs to the PHY. The transformer also attenuates common mode noise. Therefore, the circuit makes multi-use of the isolation transformer, allowing fewer components to be used for the DC coupling, wire termination, and common mode noise cancellation.

Abstract: A PHY is coupled across split primary windings of an isolation transformer for differential data transmission and reception between PHYs and for DC isolation. Positive and negative low impedance terminals of a DC power supply are coupled to first and second secondary windings of the transformer as split center taps of the transformer. Respective ends of the wires in the wire pair are coupled to the other ends of the secondary windings. Therefore, the power supply conducts DC current through the secondary windings, while the differential data signals also flow through the secondary windings, generating corresponding differential data signals at the inputs to the PHY. The transformer also attenuates common mode noise. Therefore, the circuit makes multi-use of the isolation transformer, allowing fewer components to be used for the DC coupling, wire termination, and common mode noise cancellation.