Patent Description:
A Power over Ethernet (PoE) technology can be used to transmit data and electric power on a twisted pair cable. The PoE system allows a single cable to provide both data connection and electric power to one or more powered devices such as wireless access points, IP cameras, and VolP phones. There are several techniques for transmitting power over an Ethernet cable. An Ethernet cable generally includes four pairs. For 100BASE-T and 100BASE-TX, only two of the four pairs in the cable are used. <FIG> shows a traditional PoE system. The PoE system <NUM> may include a power sourcing equipment (PSE) <NUM> and a powered device (PD) <NUM>. The PSE <NUM> includes a PSE module <NUM> that controls one or more operations of the PSE <NUM> (e.g., the detection and classification during power up of a PoE link, voltage turn on, current control, etc.). In some cases, two pairs of the twisted pair cable (e.g., the pair of lines <NUM> and <NUM>, and the pair of lines <NUM> and <NUM>) are used, and power can be supplied (from the PSE <NUM> to the PD <NUM>) in common mode over the two pairs. As illustrated in <FIG>, the network connector <NUM> of the PSE <NUM> and the network connector <NUM> of the PD <NUM> are generally registered jack <NUM> (also referred to herein as RJ45) connectors. In some cases, during power supply, a voltage +<NUM> V and a voltage <NUM> V are applied to the pair of lines <NUM> and <NUM> and the pair of lines <NUM> and <NUM>, respectively. For example, the voltage +<NUM> V is applied to the pair of lines <NUM> and <NUM>, and the voltage <NUM> V is applied to the pair of lines <NUM> and <NUM>. As another example, the voltage +<NUM> V is applied to the pair of lines <NUM> and <NUM>, and the voltage <NUM> V is applied to the pair of lines <NUM> and <NUM>. Each pair of the two pairs operates in common mode as one side of a direct current (DC) power supply fed to the PD <NUM>.

With the development of communication technology (e.g., signal modulation technology), one or more new forms of network transmission, such as 100BASE-T1 and 1000BASE-T1, are developed. For the new form(s) of network transmission, the power can be supplied by a power sourcing equipment (PSE) over a single pair to a powered device (PD). Besides, Ethernet data (also referred to herein data signal(s)) can be transmitted over the single pair. The technology of transmitting the power and Ethernet data via a single pair can also be referred to as Enhanced PoE (EPoE). <FIG> shows an EPoE system <NUM>. The EPoE system <NUM> includes a PSE <NUM> and a PD <NUM>. The PSE <NUM> and the PD <NUM> are connected via a cable <NUM>. The cable <NUM> can be connected to the connector <NUM> of the PSE <NUM> and the connector <NUM> of the PD <NUM>. As illustrated in <FIG>, the connectors <NUM> and <NUM> are generally RJ45 connectors. During power supply, the power is applied over a single pair (e.g., the pair of lines <NUM> and <NUM>) of the four pairs of the cable <NUM>. A voltage +<NUM> V and a voltage <NUM> V can be applied over the lines <NUM> and <NUM>, respectively. In the EPoE system <NUM>, the power can be supplied in a differential mode and the data signals can also be transmitted in differential mode. The frequency of the power supply is relatively low, while the frequency of the Ethernet data is relatively high. Therefore, a high pass filter and/or a low pass filter can be used to separate the power supply and the Ethernet data.

However, because of a relatively long transmission distance between the PSE and the PD in practical use, the pair of lines may be cross connected when connecting the PSE and the PD (that is, the PSE and the PD are connected via a crossover cable), which may reverse the polarity of the data signals, and influence the transmission and analysis of the Ethernet data. It may be difficult for an operator to detect whether the pair of lines are cross connected or not. Therefore, it is desirable to design systems and methods for adapting the polarity of the data signals, so that the Ethernet data can be analyzed correctly. Relevant prior art documents are <CIT> and <CIT>.

The present disclosure provided herein relates to systems and method for adapting a polarity of a data signal. Regardless of whether the single pair of lines connecting a PSE and a PD of a (E)PoE system is connected correctly or not, the polarity of the data signal can be adapted to the (E)PoE system. The adaptation of the data signal can be realized by using a polarity correction circuit. In some embodiments, the polarity correction circuit can be built in the PD of the (E)PoE system. In some embodiments, the polarity correction circuit can be built in a transformer connected between the PSE and the PD. In some embodiments, whether the single pair of lines connecting the PSE and the PD is connected correctly or not can be determined based on a polarity of a DC voltage transmitted to the PD (e.g., an input of a bridge circuit of the PD). In response to a determination that the single pair of lines connecting the PSE and the PD is not connected correctly, a switching module of the polarity correction circuit may reverse the polarity of the data signal received from the PD. After the polarity of the data signal is adapted, the data signal with an adapted polarity may be transmitted from the PD to the PSE. The PSE may receive the data signal with the adapted polarity, and analyze the data signal correctly.

<FIG> and <FIG> are schematic diagrams illustrating exemplary PoE systems according to some embodiments of the present disclosure. The PoE system 100a or 100b may include a power sourcing equipment (PSE) <NUM>, a powered device (PD) <NUM>, and a network cable connecting the PSE <NUM> and the PD <NUM>.

The PSE <NUM> may be used to manage a power supply process in the PoE system 100a or 100b. In some embodiments, the PSE <NUM> may supply electric power to the PD <NUM>. The electric power may be transmitted via the network cable. In some embodiments, the electric power may be transmitted over two pairs of lines in the network cable. For a single-pair Ethernet, the electric power may be transmitted over one pair of lines in the network cable. The one pair of lines may also transmit signals from the PSE <NUM> to the PD <NUM> and/or from the PD <NUM> to the PSE <NUM>. In some embodiments, the PSE <NUM> may be a device such as a network switch (i.e., a PoE network switch) that may supply power to one or more powered devices. The electric power may be a direct current signal (DC signal). The voltage of the DC signal may have any suitable value.

In some embodiments, the PSE <NUM> may send one or more control signals to the PD <NUM>. The control signals may be used to control the operation of the PD <NUM>, e.g., control the power up of the PD <NUM>.

In some embodiments, the PSE <NUM> may also receive a data signal from the PD <NUM>. The data signal may include a network signal, a video signal, an image signal, an audio signal, or the like, or any combination thereof. For example, if the PD <NUM> is an IP camera, the data signal may include a video signal and/or an image signal. In some embodiments, the data signal received by the PSE <NUM> may be processed by the PSE <NUM>. In some embodiments, the data signal received and/or processed by the PSE <NUM> may be transmitted to a terminal <NUM>. The terminal <NUM> may include a display <NUM>, a storage <NUM>, etc. The display <NUM> may display the received signals. The storage <NUM> may store the received signals. In some embodiments, the terminal <NUM> may also include a processing device for further processing the data received by the PSE <NUM>, a network switch for switching the data received by the PSE <NUM>, a router for routing the data received by the PSE <NUM>, or the like.

The PD <NUM> may be a device powered by the PSE <NUM> and may consume electric power. For example, the PD <NUM> may receive electric power from the PSE <NUM>. In some embodiments, the PD <NUM> may be a terminal device of the PoE system 100a or 100b. The PD <NUM> may include an IP phone, a Voice over Internet Protocol (VoIP) phone, a notebook computer, an IP camera, a Wireless Local Area Network access point, a network router, an IPTV decoder, or the like, or a combination thereof.

In some embodiments, if the PSE <NUM> and the PD <NUM> support the same transmission mode (e.g., a common-mode transmission, a differential-mode transmission), the PSE <NUM> and the PD <NUM> may be connected via a network cable as shown in <FIG>.

The network cable may transmit electric power and data signals from the PSE <NUM> to the PD <NUM>, and/or transmit data signals from the PD <NUM> to the PSE <NUM>. The network cable connecting the PSE <NUM> and the PD <NUM> may include a twisted pair cable, a coaxial cable, an optical fiber cable, or the like. The twisted pair cable may include a shielded twisted pair (STP) cable, an unshielded twisted pair (UTP) cable, or the like. The twisted pair cable may include a Category-<NUM> cable, a Category-5e cable, a Category-<NUM> cable, etc. The coaxial cable may be an RG-<NUM> coaxial cable, a <NUM>-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, or the like, or a combination thereof. The optical fiber cable may include a silica fiber cable, a fluorine doped fiber cable, a compound fiber cable, a fluoride fiber cable, a plastic optical fiber cable, or the like, or any combination thereof.

In some embodiments, if the PSE <NUM> and the PD <NUM> support different transmission modes, the transmission of power and/or data signals between the PSE <NUM> and the PD <NUM> may be realized via a transformer <NUM> as shown in <FIG>. <FIG> is a schematic diagram illustrating an exemplary transformer according to some embodiments of the present disclosure. The transformer <NUM> may include a connector <NUM> and a signal conversion module <NUM>.

The connector <NUM> may be configured to provide one or more interfaces to connect with the PSE <NUM> and/or the PD <NUM>. The connector <NUM> may include an RJ45 connector, an RJ11 connector, an SC fiber connector, an FDDI connector, an attachment unit interface (AUI) connector, a console connector, or the like, or a combination thereof.

In some embodiments, the signal conversion module <NUM> may convert an input common-mode voltage to an output differential-mode voltage. In some embodiments, the signal conversion module <NUM> may convert an input differential-mode voltage to an output common-mode voltage. In some embodiments, the signal conversion module <NUM> may include one or more circuits configured to transform the signals transmitted between the PSE <NUM> and the PD <NUM>, so that the communication between the PSE <NUM> and the PD <NUM> can be successfully realized.

In some embodiments, the transformer <NUM> may further include a polarity correction circuit <NUM>. More descriptions about the polarity correction circuit <NUM> may be found elsewhere in the present disclosure (e.g., <FIG> and the description thereof).

Through the transformer <NUM>, the PSE <NUM> and the PD <NUM> may communicate with each other successfully. The connection between the PSE <NUM> and the transformer <NUM> may be realized using a first network cable. The connection between the PD <NUM> and the transformer <NUM> may be realized using a second network cable. The first network cable connecting the PSE <NUM> and the transformer <NUM> and the second network cable connecting the PD <NUM> and the transformer <NUM> may be in the same type or in different types. The network cable may include a twisted pair cable, a coaxial cable, an optical fiber cable, or the like. The twisted pair cable may include a shielded twisted pair (STP) cable, an unshielded twisted pair (UTP) cable, or the like. The twisted pair cable may include a Category-<NUM> cable, a Category-5e cable, a Category-<NUM> cable, etc. The coaxial cable may be an RG-<NUM> coaxial cable, a <NUM>-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, an RG-<NUM> coaxial cable, or the like, or a combination thereof. The optical fiber cable may include a silica fiber cable, a fluorine doped fiber cable, a compound fiber cable, a fluoride fiber cable, a plastic optical fiber cable, or the like, or any combination thereof. In some embodiments, if the electric power is transmitted from the PSE <NUM> to the transformer in common mode and transmitted from the transformer to the PD <NUM> in differential mode, then two pairs of lines in the first network cable may be used to connect the PSE <NUM> and the transformer, and a single pair of lines in the second network cable may be used to connect the transformer and the PD <NUM>. In some embodiments, if the electric power is transmitted from the PSE <NUM> to the transformer in differential mode and transmitted from the transformer to the PD <NUM> in common mode, then a single pair of lines in the first network cable may be used to connect the PSE <NUM> and the transformer, and two pairs of lines in the second network cable may be used to connect the transformer and the PD <NUM>.

<FIG> is a schematic diagram illustrating an exemplary PSE according to some embodiments of the present disclosure. The PSE <NUM> may include a PSE interface <NUM>, a power supply <NUM>, a PSE module <NUM>, and/or a connector <NUM>.

The PSE interface <NUM> may provide a communication interface for one or more terminals. The PSE interface <NUM> may receive data and/or information from the terminal(s), and/or send data and/or information to the terminal(s). The terminal(s) may include a display, a storage, a processing device, a network switch, a router, etc. The PSE interface <NUM> may include an RJ45 connector, an RJ11 connector, a SC fiber connector, an FDDI connector, an attachment unit interface (AUI) connector, a console connector, or the like, or a combination thereof. In some embodiments, the PSE interface <NUM> may communication with the PD <NUM> via the connector <NUM>. In some embodiments, the PSE interface <NUM> may include one or more signal processing units (e.g., signal demodulation circuit(s), or the like) configured to process the data and/or information. For example, if the PSE <NUM> receives a modulated signal from the PD <NUM>, then the PSE interface <NUM> may demodulate the signal, and/or send the demodulated signal to the terminal(s).

The power supply <NUM> may provide power (e.g., a DC voltage/current signal) to the PSE <NUM> (e.g., the PSE module <NUM>). The PSE module <NUM> may include a PSE control circuitry configured to control one or more operations of the PSE <NUM> (e.g., the detection and classification of one or more PDs during the power up of the PoE system 100a or 100b). In some embodiments, the PSE module <NUM> may control the application of the DC signal to one line of the single pair of lines in the network cable connecting the PSE <NUM> and a PD. In some embodiments, the PSE module <NUM> may control the application of a ground signal to the other line of the single pair of lines in the network cable connecting the PSE <NUM> and the PD. For example, as shown in <FIG>, the PSE module <NUM> may control the application of a DC voltage of 53V to line <NUM> of the pair of lines <NUM> and <NUM> of the network cable <NUM> and control the application of a ground signal to line <NUM> of the pair of lines <NUM> and <NUM> of the network cable <NUM>. In some embodiments, the PSE module <NUM> may control the application of the DC signal to a pair of two lines in the network cable. In some embodiments, the PSE module <NUM> may control the application of a ground signal to another pair of two lines in the network cable. For example, as shown in <FIG>, the PSE module <NUM> of the PSE <NUM> may control the application of a DC voltage of 53V to the pair of lines <NUM> and <NUM> of the network cable <NUM> and control the application of a ground signal to the pair of lines <NUM> and <NUM> of the network cable <NUM>.

The connector <NUM> may be configured to facilitate the connection of the PSE <NUM> to one or more PDs and/or one or more transformers. In some embodiments, the connector <NUM> may include an RJ45 connector (e.g., the network connector <NUM> of the PSE <NUM>, the network connector <NUM> of the PSE <NUM>, or the like).

<FIG> is a schematic diagram illustrating an exemplary PD according to some embodiments of the present disclosure. <FIG> is a schematic diagram illustrating another exemplary PD according to some embodiments of the present disclosure. The PD 120a or 120b may include a PD interface <NUM>, a PD module <NUM>, a load <NUM>, a bridge circuit <NUM>, and a connector <NUM>. In some embodiments, the PD 120b may further include a polarity correction circuit <NUM>.

The PD interface <NUM> may provide a communication interface for the load <NUM> of the PD 120a or 120b. In some embodiments, the PD interface <NUM> may receive data and/or information from the load <NUM> and/or send the data and/or information to the PSE <NUM>. In some embodiments, the PD interface <NUM> may communication with the PSE <NUM> via the connector <NUM>. In some embodiments, the PD interface <NUM> may include one or more signal processing units (e.g., signal modulation circuit(s), or the like) configured to process the data and/or information. For example, the PD interface <NUM> may modulate the signals received from the load <NUM>, and transmit the modulated signal to the PSE <NUM>.

The PD module <NUM> may include one or more circuits used in one or more operations associated with the detection and/or classification of the PD 120a or 120b performed by the PSE <NUM>. In some embodiments, the PD module <NUM> may present a variable resistance. If different voltages are applied to the PD module <NUM>, the PD module <NUM> may present different resistances.

The load <NUM> may be configured to detect or collect signals, or maintain one or more functions of the PD 120a or 120b. The load <NUM> may consume electric power. In some embodiments, the load <NUM> may include one or more electricity consuming elements of the PD 120a or 120b. An exemplary load may include an IP phone, a Voice over Internet Protocol (VoIP) phone, a notebook computer, an IP camera, a Wireless Local Area Network access point, a network router, an IPTV decoder, or the like. In some embodiments, the load <NUM> may be integrated in the PD 120a or 120b. In some embodiments, the load <NUM> may be configured as a separate device, and the load <NUM> and the PD 120a or 120b may be connected by one or more external cables that transmit power from the PD 120a or 120b to the load <NUM> and transmit data signals between the load <NUM> and the PD 120a or 120b.

The bridge circuit <NUM> may be configured to rectify a polarity of a DC voltage supplied to the load <NUM>. No matter what the polarity of the DC voltage input to the bridge circuit <NUM>, the polarity of the DC signal output by the bridge circuit <NUM> is the same (e.g., the same as a predetermined polarity). In some embodiments, the predetermined polarity may be predefined in a communication protocol of the PSE <NUM> and the PD 120a or 120b. The bridge circuit <NUM> may include an input terminal. The input terminal may be configured to couple to a PoE network and receive the DC voltage from a PSE (e.g., the PSE <NUM>). In some embodiments, the bridge circuit <NUM> may also include a rectifier bridge. The rectifier bridge may include a diode bridge that may include four or more diodes in the bridge circuit configuration. The bridge circuit <NUM> may further include an output terminal for carrying a rectified version of the DC voltage. Merely by way of example, if the single pair of lines in the network cable connecting the PSE <NUM> and the PD 120a or PD 120b is connected correctly, the polarity of the DC voltage input to the bridge circuit <NUM> may be the same as the predetermined polarity, the bridge circuit <NUM> may maintain the polarity of the DC voltage, and accordingly the polarity of the DC signal output by the bridge circuit <NUM> are also the same as the predetermined polarity. As another example, if the single pair of lines in the network cable connecting the PSE <NUM> and the PD 120a or PD 120b is cross connected, the polarity of the DC voltage input to the bridge circuit <NUM> may be reversed from the predetermined polarity, the bridge circuit <NUM> may reverse the polarity of the DC voltage, and accordingly the polarity of the DC signal output by the bridge circuit <NUM> are the same as the predetermined polarity.

The connector <NUM> may be configured to facilitate the connection of the PD 120a or 120b to a PSE and/or one or more transformers. An exemplary connector of the PD 120a or 120b may be found in <FIG> (e.g., the connector <NUM> illustrated in <FIG>, the connector <NUM> illustrated in <FIG>, or the like). In some embodiments, the connector <NUM> may include an RJ45 connector (e.g., the network connector <NUM> of the PD <NUM>, the network connector <NUM> of the PD <NUM>, the RJ45 connector <NUM> of the PD <NUM>, or the like).

In some embodiments, the PD 120b may further include a polarity correction circuit <NUM> as shown in <FIG>. In some embodiments, the polarity correction circuit <NUM> may be configured to detect a polarity of a DC voltage transmitted to the PD 120b. In some embodiments, the polarity correction circuit <NUM> may be configured to adapt a polarity of a data signal from the PD 120b such that the polarity of the data signal is accordant with the polarity of the DC voltage. More description about the polarity correction circuit <NUM> may be found elsewhere in the present disclosure (e.g., <FIG> and the description thereof).

In some embodiments, as shown in <FIG>, in a single-pair Ethernet, the PD120a or 120b may support differential-mode power supply.

In some embodiments, the PD 120a or 120b may be configured as a built-in PD or an external PD. The built-in PD may refer to a powered device having a built-in connector and/or a PD interface that support a single-pair Ethernet. The external PD may refer to a powered device cooperating with an external transformer that support a single-pair Ethernet. <FIG> shows an exemplary built-in PD according to some embodiments of the present disclosure. The built-in PD <NUM> may include a connector <NUM> and a PD interface <NUM>. The built-in PD <NUM> may support differential-mode power supply, and the connector <NUM> and/or the PD interface <NUM> may support the single-pair Ethernet. The communication between the PSE <NUM> and the built-in PD <NUM> may be realized by a single pair of lines in the network cable connecting the connector <NUM> of the PSE <NUM> and the connector <NUM> of the built-in PD <NUM>. The connector <NUM> may receive power and data from the single pair of lines of the network cable and may transmit the power and data to one or more components of the built-in PD <NUM> via a single pair of lines set inside the built-in PD <NUM>. The connector <NUM> may be any suitable connector, e.g., an RJ45 connector, an RJ11 connector, a SC fiber connector, an FDDI connector, an attachment unit interface (AUI) connector, a console connector, etc. <FIG> shows an exemplary external PD according to some embodiments of the present disclosure. The external PD <NUM> may include a PD interface <NUM> and a connector <NUM>. The PD interface <NUM> may communicate with the PSE <NUM> through one or two pairs of lines. The external PD <NUM> may support common-mode power supply, and the connector <NUM> and/or the PD interface <NUM> may not directly support the single-pair Ethernet. Therefore, an external transformer <NUM> may be used to cooperate with the external PD <NUM> so that the external PD <NUM> can support the single-pair Ethernet. In some embodiments, the external transformer <NUM> may convert the differential-mode power supply into the common-mode power supply. In some embodiments, if the PD interface <NUM> is incompatible with the PSE interface <NUM> of the PSE <NUM>, the external transformer <NUM> may transform the signals transmitted between the PSE <NUM> and the PD 120a or 120b. More descriptions of the external transformer <NUM> may be found elsewhere in the present disclosure (e.g., <FIG> and the description thereof).

<FIG> is a schematic diagram illustrating an exemplary polarity correction circuit according to some embodiments of the present disclosure. The polarity correction circuit <NUM> may include a detection module <NUM> and a switching module <NUM>. An exemplary configuration of the polarity correction circuit <NUM> may be referred to the polarity correction circuit <NUM> shown in <FIG>.

In some embodiments, the detection module <NUM> may be configured to detect a polarity of a DC voltage transmitted from a PSE (e.g., the PSE <NUM>) or to a powered device (e.g., the PD 120a or 120b). In some embodiments, the detection module <NUM> may be configured to generate one or more control signals based on the polarity of the DC voltage. In some embodiments, the detection module <NUM> may generate a first control signal in response to the polarity of the DC voltage being accordant with a predetermined polarity. The first control signal may be configured to control the switching module <NUM> to maintain the polarity of the data signal(s) as received. In some embodiments, the detection module <NUM> may generate a second control signal in response to the polarity of the DC voltage being inverted from the predetermined polarity. The second control signal may be configured to control the switching module <NUM> to reverse the polarity of the data signal(s). In some embodiments, the detection module <NUM> may further determine a voltage difference associated with the DC voltage. In some embodiments, the detection module <NUM> may detect the polarity of the DC voltage by detecting the voltage difference. In some embodiments, if the polarity of the DC voltage is inverted from the predetermined polarity and the voltage difference is greater than a threshold, the detection module <NUM> may generate the second control signal. An exemplary configuration of the detection module <NUM> may be referred to the detection module <NUM> shown in <FIG>. In some embodiments, the detection module <NUM> may include a comparator or an operational amplifier.

In some embodiments, the switching module <NUM> may be configured to receive the one or more control signals. In some embodiments, the switching module <NUM> may be configured to receive one or more data signals transmitted from the powered device. In some embodiments, the switching module <NUM> may be configured to adapt a polarity of the data signal(s) based on the one or more control signals such that the polarity of the data signal is accordant with the polarity of the DC voltage. In some embodiments, the switching module <NUM> may maintain the polarity of data signal as received upon receiving the first control signal. In some embodiments, the switching module <NUM> may reverse the polarity of the data signal upon receiving the second control signal. An exemplary configuration of the switching module <NUM> may be referred to the switching module <NUM> shown in <FIG>.

<FIG> is a schematic diagram illustrating a process and/or method of adapting a polarity of a data signal according to the present disclosure. In some embodiments, the process and/or method <NUM> may be performed by the polarity correction circuit <NUM>.

In <NUM>, the polarity correction circuit <NUM> (e.g., the detection module <NUM>) detects a polarity of a DC voltage transmitted to the PD <NUM>. In some embodiments, the detecting of the polarity of the DC voltage transmitted to the PD <NUM> may be achieved by detecting a voltage difference on two lines that transmit the DC voltage to the PD <NUM>. For example, as shown in <FIG>, the PD may be supplied with the DC voltage through line a and line b. The detection module <NUM> may detect the voltage difference on line a and line b. The voltage signals on lines a and b are inputs of the bridge circuit U4. In some embodiments, the voltage difference may be determined by subtracting the voltage on line b from the voltage on line a. If the voltage on line a is larger than or equal to the voltage on line b, the polarity of the DC voltage may be positive; if the voltage on line a is smaller than the voltage on line b, the polarity of the DC voltage may be negative. In some embodiments, the voltage difference may be determined by subtracting the voltage on line a from the voltage on line b. If the voltage on line b is larger than or equal to the voltage on line a, the polarity of the DC voltage may be positive; if the voltage on line b is smaller than the voltage on line a, the polarity of the DC voltage may be negative. In some embodiments, the polarity correction circuit <NUM> may be integrated in the PD 120b, and the detection module <NUM> may detect the polarity of the DC voltage before the voltage signal is rectified by the bridge circuit <NUM> of the PD 120b. In some embodiments, the polarity correction circuit <NUM> may be integrated in the transformer <NUM>, and the detection module <NUM> may detect the polarity of the DC voltage before the voltage signal is transmitted to the PD 120a.

In <NUM>, the polarity correction circuit <NUM> (e.g., the detection module <NUM>) generates one or more control signals based on the polarity of the DC voltage. In some embodiments, if the polarity of the DC voltage is accordant with a predetermined polarity, the detection module <NUM> may generate a first control signal. The first control signal may be configured to control the switching module <NUM> to maintain the polarity of the data signal(s) as received. In some embodiments, if the polarity of the DC voltage is inverted from the predetermined polarity, the detection module <NUM> may generate a second control signal. The second control signal may be configured to control the switching module <NUM> to reverse the polarity of the data signal(s). In some embodiments, if the polarity of the DC voltage is inverted from the predetermined polarity and the voltage difference associated with the DC voltage (e.g., the absolute value of the voltage difference associated with the DC voltage) is greater than a threshold, the detection module <NUM> may generate the second control signal.

The predetermined polarity of the DC voltage may be associated with a standard or protocol relating to the communication between the PSE <NUM> and the PD 120a or 120b and is related to the connection of the single pair of lines connecting the PSE <NUM> and the PD 120a or 120b in the PoE system 100a or 100b. For example, as shown in <FIG>, a voltage +53V is applied to the pin <NUM> of the RJ45 connector of the PSE <NUM>, and a relatively low voltage is applied to the pin <NUM> of the RJ45 connector of the PSE <NUM>. If the pin <NUM> of the RJ45 connector of the PSE <NUM> connects with the pin <NUM> of the RJ45 connector of the PD <NUM>, and the pin <NUM> of the RJ45 connector of the PSE <NUM> connects with the pin <NUM> of the RJ45 connector of the PD <NUM>, it may be definitive that the voltage on line a (an input of the bridge circuit in <FIG>) is larger than the voltage on line b (another input of the bridge circuit in <FIG>). For description convenience, the voltage on line a is expressed as Va, the voltage on line b is expressed as Vb, the voltage difference, Va minus Vb is expressed as Vab, and Vb minus Va is expressed as Vba. Therefore, as illustrated in <FIG>, if the PSE and the PD are connected by the single pair of lines correctly, it may also be definitive that which of the voltage on line a (Va) and the voltage on line b (Vb) in <FIG> is relatively high and which of the voltage on line a (Va) and the voltage on line b (Vb) in <FIG> is relatively low, i.e., the predetermined polarity of Vab is definitive. If the polarity of Vab detected by the detection module <NUM> is accordant with the predetermined polarity of Vab, it may indicate that the PSE and the PD are connected correctly. If the polarity of Vab detected by the detection module <NUM> is inverted from the predetermined polarity of Vab, it may indicate that the PSE and the PD are not connected correctly.

As shown in <FIG>, the detection module <NUM> may receive Va and Vb, and Va and Vb may control the status of the voltage-regulator tube D1 and the status of the optical couple device U1. The status of the optical couple device U1 may further influence the voltage on point g (represented as Vg). For example, if the value of the electric current flowing through the optical couple device U1 is larger than or equal to the conduction current of the optical couple device U1 (e.g., <NUM> A), the optical couple device U1 may be conducted and point g is grounded. If the electric current flowing through the optical couple device U1 is smaller than the conduction current of the optical couple device U1, the optical couple device U1 may not be conducted and the voltage on point g (Vg) may be equal to Vcc. The voltages on point g (Vg) corresponding to different status of U1 may be designated as the one or more control signals.

In <NUM>, the polarity correction circuit <NUM> (e.g., the switching module <NUM>) receives one or more data signals transmitted from the PD 120a or 120b and the one or more control signals from the detection module <NUM>. In some embodiments, the switching module <NUM> may receive the data signal(s) through the PD interface <NUM> of the PD 120a or 120b. In some embodiments, the polarity correction circuit <NUM> may be integrated in the PD 120b, and the switching module <NUM> may receive the data signal(s) through the PD interface <NUM> of the PD 120b. In some embodiments, the polarity correction circuit <NUM> may be integrated in the transformer <NUM>, and the switching module <NUM> may receive the data signal(s) through the PD interface <NUM> of the PD 120a.

In <NUM>, the polarity correction circuit <NUM> (e.g., the switching module <NUM>) adapts a polarity of the data signal(s) based on the one or more control signals such that the polarity of the data signal is accordant with the polarity of the DC voltage. If the first control signal is received by the switching module <NUM>, the switching module <NUM> may maintain the polarity of the data signal(s) as received. If the second control signal is received by the switching module <NUM>, the switching module <NUM> may reverse the polarity the data signal. After the polarity of the data signal(s) is adapted, the PSE <NUM> can analyze the data signal(s) correctly. In some embodiments, the polarity correction circuit <NUM> may be integrated in the PD 120b, and the switching module <NUM> may adapt the polarity of the data signal(s) received from the load <NUM> of the PD 120b. In some embodiments, the polarity correction circuit <NUM> may be integrated in the transformer <NUM>, and the switching module <NUM> may adapt the polarity of the data signal(s) transmitted from the connector <NUM> of the PD 120a.

The detection module <NUM> shown in <FIG> includes the voltage-regulator tube D1 and the optical couple device U1. Electrical isolation may be realized in the PoE system 100a or 100b by using the optical couple device U1. The voltage-regulator tube D1 may include a first cathode and a first anode. The optical couple device U1 may include a light emitting device and a light receiving device. The light emitting device may be a light-emitting diode including a second cathode and a second anode. The light receiving device may include a phototransistor. As illustrated in <FIG>, the first anode of the voltage-regulator tube D1 may be in connection with the second anode of the light-emitting diode, and the first cathode of the voltage-regulator tube D1 may be in connection with line b.

If the predetermined polarity of Vab is positive, and the detected polarity of Vab is also positive (i.e., the PSE <NUM> and the PD 120a or 120b are connected correctly), no matter what the value of Vab is, the optical couple device U1 may not be conducted and the voltage on point g (Vg) may be always a relatively high-level voltage (i.e., the first control signal may be a relatively high-level voltage). In this case, Vg may control the switching module <NUM> (e.g., the switch units U2 and U3) to maintain the polarity of the data signal(s) as received, e.g., control a switch SW1 to connect with line e and control a switch SW2 to connect with line f.

If the predetermined polarity of Vab is positive, the detected polarity of Vab is negative (i.e., the PSE <NUM> and the PD 120a or 120b are not connected correctly), the regulation voltage of the voltage-regulator tube D1 is Vregulation (e.g., <NUM> V), the conduction current of the optical couple device U1 is Cconduction (e.g., <NUM> A), the conduction voltage of the light-emitting diode of the optical couple device U1 is Vconduction (e.g., <NUM> V), the resistances of resistor R1 and resistor R2 are the same (e.g., <NUM> ohms), and Vba is smaller than the regulation voltage of the voltage-regulator tube D1 (e.g., <NUM> V), then the voltage-regulator tube D1 may not be conducted, the optical couple device U1 may also be not conducted, and the voltage on point g may be a relatively high-level voltage (e.g., Vcc). When Vba is relatively small, the PoE system 100a or 100b may be in detection or classification process. If Vba is larger than Cconduction*R1+Vconduction+Vregulation (e.g., <NUM> V), then the optical couple device U1 may be conducted, point g may be grounded, and the voltage on point g (Vg) may be zero (i.e., the second control signal may be a ground signal). In this case (Vg is a relatively low-level voltage, e.g., zero), Vg may control the switching module <NUM> (e.g., the switch units U2 and U3) to reverse the polarity of the data signal(s), e.g., control the switch SW1 to connect with line f and control the switch SW2 to connect with line e. After the polarity of the data signal(s) is reversed, the PSE <NUM> can analyze the data signal(s) correctly. When Vba is equal to or larger than a predetermined value (e.g., a power-supply voltage of the PD 120a or 120b), the PoE system 100a or 100b may be in power supplying process. In some embodiments, the adaptation of the polarity of the data signal(s) may be implemented only in the power supplying process.

If the predetermined polarity of Vab is negative, but the detected polarity of Vab is positive (i.e., the PSE <NUM> and the PD 120a or 120b are not connected correctly), then no matter what the value of Vab is, the optical couple device U1 may not be conducted, and the voltage on point g (Vg) may be always a relatively high-level voltage (i.e., the second control signal may be a relatively high-level voltage). In this case, Vg may control the switching module <NUM> (e.g., the switch units U2 and U3) to reverse the polarity of the data signal(s), e.g., control the switch SW1 to connect with line f and control the switch SW2 to connect with line e. After the polarity of the data signal(s) is reversed, the PSE <NUM> can analyze the data signal(s) correctly.

If the predetermined polarity of Vab is negative, the detected polarity of Vab is also negative (i.e., the PSE <NUM> and the PD 120a or 120b are connected correctly), the regulation voltage of the voltage-regulator tube D1 is Vregulation (e.g., <NUM> V), the conduction current of the optical couple device U1 is Cconduction (e.g., <NUM> A), the conduction voltage of the light-emitting diode of the optical couple device U1 is Vconduction (e.g., <NUM> V), the resistances of resistor R1 and resistor R2 are the same (e.g., <NUM> ohms), Vba is smaller than the regulation voltage of the voltage-regulator tube D1 (e.g., <NUM> V), then the voltage-regulator tube D1 may not be conducted, the optical couple device U1 may also be not conducted, and the voltage on point g may be a relatively high-level voltage (e.g., Vcc). If Vba is larger than Cconduction*R1+Vconduction+Vregulation (e.g., <NUM>. 7V), the optical couple device U1 may be conducted, point g may be grounded, and the voltage on point g (Vg) may be zero. In this case (the first control signal Vg is a relatively low-level voltage, e.g., zero), Vg may control the switching module <NUM> (e.g., the switch units U2 and U3) to maintain the polarity of the data signal(s) as received, e.g., control the switch SW1 to connect with line e and control the switch SW2 to connect with line f.

It should be noted that the description about the detection module <NUM> and the switching module <NUM> are merely examples, and should not be limiting. In some embodiments, the connection between the voltage-regulator tube D1 and the optical couple device U1 may be changed. For example, the first anode of the optical couple device U1 may be in connection with line b, the first cathode of the voltage-regulator tube D1 may connect with the second cathode (or the second anode) of the optical couple device U1. In some embodiments, the detecting module <NUM> may include a comparator or an operational amplifier which may also realize the functions of the detection module <NUM> shown in <FIG>. As illustrated In <FIG>, the switching module <NUM> may include two switching units U2 and U3. The switching unit U2 may include a single-pole double-throw switch SW1. The switching unit U3 may include a single-pole double-throw switch SW2. In some embodiments, the switching module <NUM> may include one or more components that are configured to switch a pair of lines that transmit the received data signal(s) (e.g., lines e and f illustrated in <FIG>). For example, the switching module <NUM> may include one switching unit that may include a double-pole four-throw switch. The double-pole four-throw switch may also adapt the polarity of the data signal based on the one or more control signals received.

<FIG> is schematic diagram illustrating variation of signals transmitted in an exemplary PoE system according to some embodiments of the present disclosure.

If a device connects with a PSE, power can be injected onto the cable connecting the PSE and the device at a suitable voltage, for example, between <NUM> V and <NUM> V. This relatively high voltage may allow efficient power transfer along the cable. However, the relatively high voltage may damage the device if the device does not support PoE. Therefore, before the PSE enable power to the device, the PSE may perform a detection process (stage <NUM> in <FIG>). The detection process may be performed to determine whether the device is a PD. During the detection process, a lower voltage may be used. For example, a detection voltage may be applied. The detection voltage may be any suitable value. In some embodiments, the detection voltage may be <NUM> V.

In some embodiments, after the detection process, a classification process (stage <NUM> in <FIG>) may be performed. The classification process may be performed to classify the PD, e.g., determine the power budget for the PD. During the classification process, a classification voltage larger than the detection voltage may be applied to the PD. The classification voltage may be any suitable value, for example, <NUM>-<NUM> V. In some embodiments, the classification voltage may be <NUM> V.

After one or more times of detection and classification processes, the PoE may enter a stage of power supplying (stage <NUM> in <FIG>) to supply power to the PD. The power-supply voltage may be any suitable value. In some embodiments, the power-supply voltage may be <NUM> V. If the PD disconnects from the PSE, the PoE may stop supplying power to the PD (stage <NUM> in <FIG>).

As described above, in some embodiments, if the PD and the PSE are not connected correctly (e.g., the PSE and the PD are connected via a crossover cable), during stage <NUM> and stage <NUM>, the voltage on point g (Vg) may be a relatively low voltage (e.g., <NUM> V), and the polarity of the data signal(s) may be maintained; during stage <NUM>, the voltage on point g (Vg) may be a relatively high voltage (e.g., a voltage Vcc), and the polarity of the data signal(s) may be reversed to be accordant with the polarity of the DC voltage. It should be noted that in some embodiments, as illustrated in <FIG>, the adaptation of the polarity of the data signal(s) may be implemented only in the power supplying process, which may improve the stability of the PoE system 100a or 100b.

Claim 1:
A polarity correction circuit (<NUM>) for a system (100a, 100b) of Power over Ethernet (PoE), comprising:
a detection module (<NUM>), configured to detect a polarity of a DC voltage transmitted from a Power of Sourcing Equipment (PSE) (<NUM>) to a powered device (<NUM>) and generate one or more control signals based on the polarity of the DC voltage, wherein a predetermined polarity of the DC voltage is related to a connection of a single pair of lines connecting the PSE (<NUM>) and the powered device (<NUM>), and whether the PSE (<NUM>) and the powered device (<NUM>) are connected correctly is indicated by whether the polarity of the DC voltage is accordant with the predetermined polarity of the DC voltage; and
a switching module (<NUM>), configured to:
receive the one or more control signals and a data signal, the data signal being transmitted from the powered device (<NUM>); and
adapt a polarity of the data signal based on the one or more control signals such that the polarity of the data signal is accordant with the polarity of the DC voltage, before the data signal being transmitted to the PSE (<NUM>).