POEPHYTEREV-I

User's Guide SNOA476C – October 2006 – Revised April 2013 AN-1521 POEPHYTEREV-I / -E Evaluation Board 1 Introduction The POEPHYTEREV-I/-E evaluation board is a seamless design demonstrating Texas Instruments LM5072 PoE product (capable of up to 24W) and DP83848I (single port 10/100Mb/s) Ethernet PHYTER® product. While both the LM5072 and the DP83848 Ethernet PHY device have many advanced and enticing features, this specific board is designed to demonstrate a subset of those features, specifically Power over Ethernet. Two versions of this board are available. The –I version has an RJ-45 connector that with integrated Ethernet magnetics. The –E version has discrete RJ-45 connector and Ethernet magnetics. The schematics of the board are available with this kit for duplication into an end application product. For additional features of the PoE and PHY devices, individual device evaluation boards are separately available. For detailed information about the complete functions and features of the LM5072 or DP83848 devices, refer to the relevant data sheets. For applications where IEEE 802.3af must be complied with and the power level is below 12.95W, refer to AN-1455 LM5072 Evaluation Board (SNVA154). For detailed information about the Ethernet PHYTER® circuit, refer to AN-1469 PHYTER® Design & Layout Guide (SNLA079). This evaluation kit contains: • POEPHYTEREV-I or –E Evaluation board • Printed copy of this User's Guide • Board schematic • End User Licensing Agreement (EULA) 2 Scope of Applications The POEPHYTEREV-I/-E evaluation kit (EK) is designed for high power PD (PoE terminology - Powered Device) applications in which the maximum power exceeds the IEEE 802.3af’s 12.95W limit. The evaluation board features TI™’s DP83848 10/100 Mb/s PHYTER® Ethernet Physical Layer Transceiver, so any equipment that provides a standard IEEE 802.3, Clause 22 MII DTE interface; e.g. SmartBits/Netcom box, is required as a data source for the Ethernet device. The LM5072 is a 100V, high power PoE PD and PWM controller. The evaluation board is capable of operating with both PoE and auxiliary (AUX) power sources. The dc-dc converter stage of the power supply is implemented in the versatile flyback converter topology. 3 Important Note on Circuit Board Versions There are two versions of PCBs being built, which can be identified by the PCB serial number printed along the left edge of the top side the circuit board. One version is labelled 551012916-001 Rev A, the other 551013040-001 Rev A. The first version cannot modify the 3.3V output to higher voltages because it is directly connected to the PHY through inner layers. It is modified on the second version such that higher output voltage can be produced without damaging the PHY circuit. The factory default output setting for both versions is 3.3V. Contact TI on support to modify the latter version to other output voltage. In the following, descriptions apply to both versions of the circuit boards unless specifically indicated. TI is a trademark of Texas Instruments. All other trademarks are the property of their respective owners. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 1 Features of the Evaluation Board 4 www.ti.com Features of the Evaluation Board Seamless design solution, incorporating DP83848 PHYTER® single port 10/100 Mb/s Ethernet physical layer transceiver and LM5072 High Power PoE PD and PWM controller. Ethernet • Integrated or External magnetics and RJ45 • Minimum configuration requirements: – 2 PHY Addresses - 01h (default) or 03h – Status LEDs – board power, others dependant on LED mode selected – Limited Strap Options – MDIX_EN, LED_CFG, PWR_DWN/INT, MII/RMII Sel – RESET_N jumper – PWR_DWN/INT jumper • Connections for the following interfaces: – MIl/RMII Interface (IEEE 802.3 standard) – RJ-45 Cat-V Ethernet cable connector – JTAG header – 25MHz_OUT header – Header for “ribbon cable” connection to MII/RMII • On-board clock – Crystal/Oscillator Dual Footprint Power Over Ethernet • Isolated output voltage: 3.3V • Maximum output current: 7.3A • Maximum output power: 24W • Input voltage ranges: – PoE input voltage range: 39 to 57V – AUX input voltage range: 22 to 57V • Measured maximum efficiency: – DC to DC converter efficiency: 90% at 6A – Overall efficiency (including the input diode bridge): 86% at 6A • Overall Board Size: 5.50” x 3.96” x 0.70” • Switching frequency: 250 kHz • Optional input common-mode filter PCB Layout Considerations • FR4 material • Trace symmetry within differential pair (±0.5") • Differential impedance 100 ohms, ±5% • Adjacent differential pairs spacing > 2X distance within a differential pair, to minimize cross-talk and EMI • Trace length matching between differential pairs not required • Uniform supply & ground plane • Void planes under magnetics, except for Chassis GND (at RJ-45 edge only) • Combination of through-hole and surface mount technology • Trace/space will be 0.007”/0.008” minimum • System interface will be via the MII connector, and MII header • RJ-45 for network connection • JTAG access via 2x5 header 2 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Usage setup and Configuration www.ti.com 5 Usage setup and Configuration This section contains information about the setup and configuration of the POEPHYTEREV-I/-E evaluation board, including descriptions of the card's interfaces, connectors, jumpers and LEDs. Power for the POEPHYTEREV board can be supplied by a number of means: • MII connector J1 • PoE over unused pairs • PoE over data pairs • External supply to P1 • If 5V is supplied from the MII connector, the on-board voltage regulator, U2, will convert 5V to 3.3V for the PHYTER®. J7 should be removed. • If 3.3V is supplied from the MII connector, J7 needs to be ON (see Section 8 for details). • Only applies to the circuit board version with PCB serial number 551013040-001 Rev A: J7 should be shorted if the PoE main output is set at 3.3V, which is the default factory setting. To modify the output to other higher voltages, a 3.3V LDO should be installed onto U2 and J7 must be open. Address Settings: The PMD address for the DP83848 Physical Layer device is set by jumper J3. • Default board setting for the PHY Address is 01h • The board may be set to PHY Address 03h by adding jumper J3 Table 1. Table of Jumpers (1) Jumper Name Function J1 MII Male Connector J2 MII Header J3 PHYAD1 PHY Address strap pin J4 MDIX_EN Enable/Disable MDIX mode. (Default is Auto-MDIX Enable) J5 LED_CFG Set LED configuration. See data sheet MII interface Alternative connection for MII signals J6(Not populated) J7 MII 3V3 option Use 3V3 MII supply J8 PWR_DWN/INT J9 RESET_N Reset the device Pulse Jack Integrated Magnetic RJ-45 connector Set Power Down and Interrupt Mode. See data sheet J10 (Not populated) J11 (Not populated) J12 (1) Additional information for all options above may be found in the DP83848 data sheet. Status indicators: LEDs The POEPHYTEREV board supplies numerous status indicators via LEDs. Status provided include: Link - DS3* Media Speed - DS2 Activity/Collision - DS4* Ethernet Device Power - DS1 PoE Power - LED1 *Other status can be indicated by these LEDs. The alternate status is set by adding jumper J5. Refer to PHYTER Extreme Temperature Single Port 10/100 Mb/s Ethernet Physical Layer Data Sheet (SLLSEC6) for additional information. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 3 An Important Note About the Maximum Power Capability and Cable Usage www.ti.com Ethernet Performance The DP83848 PHYTER® supports line speed Ethernet network communications. Signal quality, which affects IEEE compliance, can vary depending on board layout, power supplies, and components used, esp. isolation magnetics. Software No device specific software is required for this board. 6 An Important Note About the Maximum Power Capability and Cable Usage The maximum output power is 24W. The user must make sure that the Power Sourcing Equipment (PSE) in use can provide at least 30W. Important: Please note that the CAT-5 cable may not support the said power over two pairs of twisted wires under strict safety considerations. Users will select the proper cable wires to support the design power level without compromising the applicable safety standards. Using an improper cable at such power levels may violate safety regulations and may cause damage. 7 A Note about PoE Input Potentials PoE applications are typically -48V systems, in which the notations GND and -48V normally refer to the high and low input potentials, respectively. However, for easy readability, the LM5072 datasheet was written in the positive voltage convention with positive input potentials referenced to the VEE pin of the LM5072. Therefore, when testing the evaluation board with a bench power supply, the negative terminal of the power supply is equivalent to the PoE system’s -8V potential, and the positive terminal is equivalent to the PoE system ground. To prevent confusion between the data sheet and this application note, the same positive voltage convention is used herein. 8 Schematics of the Evaluation Board Figure 1, Figure 2, and Figure 3 shows the schematic of the evaluation board. 4 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Schematics of the Evaluation Board www.ti.com Figure 1. Evaluation Board Schematic Part 1. The Ethernet Circuit Figure 2. Evaluation Board Schematic Part 2: RJ45 connectors and Ethernet Magentics SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 5 Connection and Proper Test Methods www.ti.com Figure 3. Evaluation Board Schematic Part 3: the PoE Circuit 9 Connection and Proper Test Methods Figure 4 shows a photo of the evaluation board with the connection ports indicated. The PoE circuit occupies the lower part of the board within the rectangular outline. The RJ45 connectors, Ethernet magnetics and PHY circuit are placed in the upper area of the board. The following are the seven connections: • J1, a 42 pin MII Connector for the Ethernet media independent interface. • JE4 through JE7, double pairs of connection pins for the 3.3V output. JE4 and JE5 of are the high potential pins • J13, a regular RJ45 connector on the -E version board for PoE input and data link • UE13, Bel Stewart Integrated RJ45 connector on the -I version board for PoE input and data link • TP7 and TP8, a pair of pins for quick PoE input connection to a bench power supply. TP7 is the high potential pin • P1, a PJ102A power jack, for Auxiliary (AUX) power input. The center pin of P1 is the high potential pin • TP3 and TP4, a pair of pins for quick AUX power input connection to a bench power supply. TP3 is the high potential pin 6 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Connection and Proper Test Methods www.ti.com Figure 4. The Connection Ports of the Evaluation Board The -E version evaluation board employs a regular RJ45 connector, J13, which is to be used with the external Ethernet magnetics assembly U4. The -I version evaluation board uses an integrated RJ45 connector, UE13, which has the Ethernet magnetics enclosed in the case. For the PoE input through either RJ45 connector, the diode bridge BR1 or BR2 is used to steer the current to the positive and negative supply pins of the LM5072, namely the VIN and VEE pins. When using TP7 and TP8 for the quick PoE input connection to a bench power supply, make sure TP7 is the high potential terminal. For the AUX power input, the higher potential should feed into the center pin of P1. When using TP3 and TP4 for the quick AUX input connection to a bench power supply, be aware that TP3 is the high potential pin. The diode DE1 provides the reverse protection of the AUX input. Please note that TP4 and TP8 are two different return pins for the PoE and AUX inputs, respectively. They are not connected to the same circuit node, and they should not be interchanged. For the output connection, the load can be either a passive resistor or active electronic load. Attention should be paid to the output polarity when connecting an electronic load. It is not recommended to use additional filter capacitors greater than 20 µF total across the output port as the extra capacitance will alter the feedback loop properties and may cause instability. If it is necessary to add extra capacitance in a particular application, the feedback loop compensation must be adjusted accordingly. Sufficiently large wire such as AWG #18 or thicker is required when connecting the source supply and load. Also, monitor the current into and out of the circuit board. Monitor the voltages directly at the board terminals, as resistive voltage drops along the connecting wires may decrease measurement accuracy. Never rely on the bench supply’s voltmeter or ammeter if accurate efficiency measurements are desired. When measuring the dc-dc converter efficiency, the converter input voltage should be measured across CE4. When measuring the evaluation board overall efficiency (which is more relevant), both input and output voltages should be read from the terminals of the evaluation board. Remember to count the power dissipation by the PHY circuit in the efficiency measurement. When the PHY circuit is in the idle mode, it will draw 55 mA from the 3.3V rail, most of which is consumed by the on-board LED indicators. Refer to the appropriate user manual or instruction for the use of the MII connector. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 7 Source Power 10 www.ti.com Source Power To fully test the evaluation board, either a high power PSE able to supply 30W or a lab bench DC power supply capable of at least 60V and 1A is required for the PoE input. For the AUX source power, use a 24V AC adapter or a DC power supply capable of 30V and 3A. Use the output over-voltage and over-current limit features of the bench power supplies to protect the board against damage by errant connections. 11 Loading/Current Limiting Behavior A resistive load is optimal, but an appropriate electronic load specified for operation down to 2.0V is acceptable. The maximum load current is 7.3A. Exceeding this current at low input voltage may cause oscillatory behavior as the circuit will go into current limit mode. Exceeding this current at high input voltage may force the DC-DC converter to run into cycle by cycle peak current limit. Current limit mode is triggered whenever the average current through the PoE connector exceeds 800 mA (setting is determined by RE23; see LM5072 Integrated 100V Pwr Over Ethernet PD Interface & PWM Cntrl w/Aux Support Data Sheet (SNVS437 for details). The circuit then runs into a retry mode (hiccups). Cycle-bycycle peak current limit mode narrows the duty cycle and hence the output voltage loses regulation and enters an under voltage condition. In both current limit modes, the circuit will not be latched off and normal operation will be automatically restored after the removal of the fault condition. 12 Power Up For the first time power up, it is recommended to apply PoE power first. The load should be kept reasonably low (under 25% of full load). Check the supply current during signature detection and classification modes before applying full power. During detection mode, the module should have the I-V characteristics of a 25 kΩ resistor in series with two diodes. During classification mode, the current draw should be about 40 mA at 16V, which is determined by RE22 of 31.6Ω. This sets the evaluation board to Class 4, which is “reserved for future use” per IEEE 802.3af, namely the high power application. If the proper response is not observed during both detection and classification modes, check the connections closely. If no current is flowing it is likely that the set of conductors feeding PoE power have been incorrectly installed. Once the proper setup has been established, full power can be applied. A voltmeter across the output terminals JE5 (3.3V) and JE6 (3.3V RTN) will allow direct measurement of the 3.3V output line. If the 3.3V output voltage is not observed within a few seconds, turn off the power supply and review connections. A final check of efficiency is the best way to confirm that the circuit is operating properly. Efficiency being significantly lower than 80% at full load indicates a problem. After proper PoE operation is verified, the user may apply AUX power. It is recommended that the application of AUX power follow the same precautions as those for PoE power application. If no output voltage is observed, it is likely that the AUX power feed polarity is reversed. After successful operation is observed, full AUX power testing can begin. 13 PD Interface Operating Modes When connecting into the PoE system, the evaluation board will go through the following operating modes in sequence: PD signature detection, power level classification (optional), and application of full power. See LM5072 Integrated 100V Pwr Over Ethernet PD Interface & PWM Cntrl w/Aux Support Data Sheet (SNVS437) for details. 14 Signature Detection The 25 kΩ PD signature resistor is integrated into the LM5072 IC. The PD signature capacitor is realized by CE29, a 100 nF capacitor. During AUX power operation, CE29 also improves the noise immunity of the IC substrate (interconnected to the VEE pin) by providing a low impedance path to the COM node. It should be noted that when AUX power is applied first, it will not allow the PSE to identify the PD as a valid device because the AUX voltage will cause the current steering diode bridges BR1 and BR2 to be reverse biased during detection mode. This prevents the PSE from applying power, so the evaluation board will only draw current from the AUX source. 8 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Classification www.ti.com 15 Classification PD classification is implemented with RE22. The evaluation board is preset to Class 4 by installing a resistor of 31.6Ω at RE22, indicating that the power consumption of the evaluation board exceeds the 12.95W limit per IEEE 802.3af. 16 Input UVLO and UVLO Hysteresis The input Under Voltage Lock-Out (UVLO) is an integrated function of the LM5072. The UVLO release threshold is set to approximately 38.5V (at the pins of the IC) and the UVLO hysteresis is approximately 7V. 17 Inrush and DC Current Limit Programming The LM5072 allows the user to independently program the inrush and DC current limits of the internal hot swap MOSFET. The evaluation board sets the inrush limit to the default 150 mA by leaving RE19 unpopulated, and the DC current limit to 800 mA by installing a 15.8 kΩ resistor at RE23. To adjust the inrush and DC current limits, use proper resistors for RE19 and RE23, respectively, according to the recommendations in LM5072 Integrated 100V Pwr Over Ethernet PD Interface & PWM Cntrl w/Aux Support Data Sheet (SNVS437). 18 Auxiliary Power Option In this evaluation board, the AUX power is configured into the AUX dominant mode. Please refer to LM5072 Integrated 100V Pwr Over Ethernet PD Interface & PWM Cntrl w/Aux Support Data Sheet (SNVS437) for details. During AUX dominance, the AUX power source will always supply the current to the PD regardless whether the PoE power is present or not. Note that auxiliary non-dominance does not imply PoE dominance. To achieve PoE dominance, additional circuitry must be employed. Because the AUX input bypasses the LM5072’s input hot swap circuit, the evaluation board uses eight 8.06Ω resistors (RE1A through RE1D and RE2A through RE2D) in parallel to achieve a low cost AUX inrush limiter and transient protection. Otherwise the unlimited inrush currents can wear on-board traces, connector contacts, and various board components, as well as create damaging transient voltages. Nevertheless, these eight resistors will cause power loss in the AUX power mode, and they also reduce the effective AUX input voltage level sensed by the VIN pin of the LM5072. A more efficient and generally better performing AUX inrush limiter can be achieved with additional circuitry employing a bipolar transistor or MOSFET. If the AUX power option is not used in a new design, delete CE3, DE1, the eight resistors RE1A through RE1D and RE2A through RE2D, RE13, RE29, and P1 to lower the BOM cost. 19 AUX Input “OR-ing” Diode Selection This diode does not need to be a high speed type since there is no switching action during operation, however, it should be a low reverse leakage current device. RE29, a 24.9 kΩ resistor is employed on the evaluation board, providing a sinking path for the leakage current of DE1. It is meant to sink all of the leakage current of DE1 and prevent a false logic state at the RAUX pin. Please see the LM5072 Integrated 100V Pwr Over Ethernet PD Interface & PWM Cntrl w/Aux Support Data Sheet (SNVS437) for more details about the selection of DE1 and RE29. 20 Flyback Converter Topology The dc-dc converter stage of the evaluation board features the flyback topology, which employs the minimum number of power components to implement an isolated power supply at the lowest possible cost. Generally, the flyback topology is best suited for applications of power levels lower than 50W. When the power level is higher, the forward, push-pull and bridge topologies will be appropriate candidates. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 9 Factors Limiting the Minimum Operating Input Voltage www.ti.com A unique characteristic of the flyback topology is its power transformer. Unlike an ordinary power transformer that simultaneously transfers the power from the primary to the secondary, the flyback transformer first stores the energy inside the transformer while the main switch is turned on, and then releases the stored energy to the load during the rest of the cycle. When the stored energy is not completely released before the main switch is turned on again, it is said that the flyback converter operates in continuous conduction mode (CCM). Otherwise, it is in discontinuous conduction mode (DCM). Major advantages of CCM over DCM include (i) lower ripple current and ripple voltage, resulting in smaller input and output filter capacitors; and (ii) lower RMS current, thus reducing the conduction losses. To keep the flyback converter in CCM at light load, the transformer’s primary inductance should be designed as large as is practical. Major drawbacks of CCM, as compared to DCM, are (i) the presence of the right-half-plane zero, which may limit the achievable bandwidth of the feedback loop, and (ii) the need for slope compensation to stabilize the feedback loop at duty cycles greater than 50%. The flyback topology can have multiple secondary windings for several isolated outputs. One or more of these secondary channels are normally utilized internally by the converter itself to provide the necessary bias voltages for the controller. The transformer uses an EFD20 type core with a primary inductance of 45 µH. The converter runs in CCM at full load over the entire input voltage range, but it will operate in DCM under light loads. The LM5072’s built-in slope compensation helps stabilize the feedback loop when the duty cycle exceeds 50% in 24V AUX power operation. A additional transformer winding is used to provide the bias voltage (VCC) to the LM5072 IC. Although the LM5072 controller includes an internal startup regulator which can support the bias requirement indefinitely, the transformer winding produces an output about 2V higher than the startup regulator output, thus shutting off the startup regulator and reducing the power dissipation inside the IC. Given the low current limit value (15 mA nominal) of the high voltage startup regulator, the VCC line is not meant to source external loads greater than 3 mA in total. The external load of the VCC line is the “PoE Power” LED indicating the PoE operation mode. 21 Factors Limiting the Minimum Operating Input Voltage The LM5072 supports operation with as low as 9V AUX power source. However, limited by the flyback power transformer design, the minimum AUX voltage of the evaluation board is 22V (voltage drops caused by RE1A and alike and DE1 reduce the VIN pin potential to about 20V). The installed EFD20 type power transformer FA2267-AL is a low cost, area efficient solution to operate with a wide auxiliary input voltage range from 24V to 57V. However, it does not support 24W power operation with the lower input voltage. Under these conditions the excessive magnetic flux may saturate the transformer core. It is possible to operate with a lower voltage AUX source, if the output power level is reduced. If full power is required under low AUX input voltage, the power transformer will need to be redesigned. 22 PoE Performance Characteristics 22.1 PoE Input Power-up Sequence The PoE power up sequence is as follows. Note that the RTN pin (IC pin 8) is isolated from the +3.3V RTN output pin of the evaluation board: 1. The circuit first enters detection mode. 2. Depending on the PSE in use, the circuit may or may not go through classification mode. 3. The PSE enters full power application mode. Before the PoE input voltage reaches the UVLO threshold, the hot swap MOSFET is in the OFF state. Thus, all nodes in the non-isolated section of the power supply remain at high potential. The voltage across the hot swap MOSFET, namely the voltage across the RTN and VEE pins, will be approximately equal to the PoE input voltage seen across the VIN and VEE pins. 4. When the UVLO is released during the PoE input power up, the drain of the internal hot swap MOSFET is pulled down to VEE (IC pin 7) gradually as the input current charges up the input capacitors. 10 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated PoE Performance Characteristics www.ti.com 5. The VCC regulator powers up during the inrush sequence. During VCC regulator startup, it draws current on the order of 20mA, but this will likely not be noticed by the user. Once the RTN pin of the IC drops below 1.5V (referenced to VEE), and the gate of the hot swap MOSFET rises, power good is asserted by pulling the nPGOOD pin low. 6. Once power good has been asserted, the SS (Soft-Start) pin is released. The SS pin will rise at a rate equal to the SS current source, typically 10 µA, divided by the SS pin capacitance, CE26. 7. After the soft start is complete, the switching regulator achieves output regulation, and the converter enters steady state operation. The auxiliary winding will raise the VCC voltage to about 10.5V, thus shutting down the internal regulator and increasing efficiency. Figure 5 shows key waveforms during a normal PoE power up sequence. Please note that the PSE used in the test goes through detection mode, but opts out of classification mode and directly enters full power application mode. Horizontal Resolution: 50 ms/div. Trace 1: PoE input voltage across the VIN and VEE pins. 20V/div. Trace 2: Voltage across the RTN and VEE pins, namely the voltage across the Hot Swap MOSFET. 20V/div. Trace 3: The input current. 0.2A/div. Trace 4: The 3.3V output voltage. 2V/div. Figure 5. PoE Power Up Sequence with a Midspan PSE 22.2 Auxiliary Input Power-up Sequence The AUX input power up sequence is simpler: 1. AUX power application quickly charges the input capacitors. The AUX input inrush limit resistors limit the inrush current and prevent any overshoot of the voltage across the VIN and RTN pins. 2. When the VCC regulator starts up, the PWM controller begins soft start. 3. After soft start, the switching regulator achieves output regulation, and the converter enters steady state operation. The auxiliary winding will raise the VCC voltage to about 10.5V, thus shutting down the internal regulator and increasing efficiency. Figure 6 shows key waveforms during a normal AUX power up sequence. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 11 PoE Performance Characteristics www.ti.com Horizontal Resolution: 5 ms/div. Trace 1: AUX input voltage (VIN to RTN pins). 10V/div. Trace 2: The 3.3V output voltage. 2V/div. Trace 3: The input current. 1A/div. Figure 6. AUX Power Up Sequence 22.3 Output Dead Short Fault Response and Over Current Protection The evaluation board survives the output dead short condition by running into re-try mode (hiccup) or cycle-by-cycle peak current limit mode, depending on the input voltage condition when the fault occurs. Applying a dead short to the +3.3V line causes a number of protection mechanisms to take place sequentially. They are: 1. The feedback signal increases the duty cycle in an attempt to maintain the output voltage. This initiates cycle-by-cycle over-current limiting which turns off the main switch when the current sense (CS) pin exceeds the current limit threshold. 2. The current in the internal hot swap MOSFET increases until it is current limited around 800 mA. Some overshoot in the current will be observed, as it takes time for the current limit amplifier to react and change the operating mode of the MOSFET. 3. Because linear current limiting is accomplished by driving the MOSET into the saturation region, the drain voltage (RTN pin) rises. When it reaches 2.5V with respect to VEE, power good is de-asserted and the nPGOOD pin voltage rises. 4. The de-assertion of power good causes the discharge of the soft-start capacitor, which disables all switching action in the dc-dc converter. 5. Once the switching stops, the current in the internal MOSFET will decrease and the drain voltage will fall back below 1.5V with respect to VEE. When power good is re-asserted, the dc-dc converter will automatically restart with a new soft-start sequence. Figure 7 and Figure 8 show cycle-by-cycle peak current limit in response to an output dead short with a 24V AUX input and 48V PoE input, respectively. The short-circuit condition results in a peak current of about 3.2A in the primary circuit. This peak current produces about 0.5V peak at the CS pin, initiating cycle-by-cycle peak current limit mode. The duty cycle is thus greatly reduced, which in turn limits the AUX input dc current to about 0.39A, and the PoE input dc current to about 0.16A, respectively. 12 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated PoE Performance Characteristics www.ti.com Horizontal Resolution: 1 µs/div. Trace 1: Current sense voltage across RE15. 0.5V/div. Trace 2: The input current from the AUX power source. 200 mA/div Figure 7. Cycle-by-cycle Peak Current Limit under AUX Input and Output Dead Short Condition Horizontal Resolution: 1 µs/div. Trace 1: Current sense voltage across RE15. 0.5V/div. Trace 2: The input current from the AUX power source. 100 mA/div Figure 8. Cycle-by-cycle Peak Current Limit under 48V PoE Input and Output Dead Short Condition Figure 9 shows key waveforms of over-current protection by the hot swap MOSFET’s dc current limit. The PoE input voltage is at 38V. The input current exceeds the 800 mA current limit of the hot swap MOSFET, and causes the voltage at the RTN pin to rise rapidly. It also discharges the soft start capacitor CE26 connected to the SS pin, and the circuit enters the automatic retry mode as long as the over-current condition is present. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 13 PoE Performance Characteristics www.ti.com Horizontal Resolution: 5 ms/div. Trace 1: The voltage of the RTN pin (referenced to the VEE pin). 0.5V/div. Trace 2: The PoE input current. 0.5A/div Figure 9. Retry Mode under 38V PoE Input and Output Over Current Condition 22.4 Step Response Figure 10 shows the step load response at Vin equal to 48V. The load current changes in step between 1A and 7A. Horizontal Resolution: 0.5 ms/div. Trace 1: Load current step changes between 1A and 7A. 2A/div. Trace 2: The 3.3V output voltage response (AC coupled). 0.5V/div. Figure 10. Output Voltage Step Load Response 14 AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated PoE Performance Characteristics www.ti.com 22.5 Ripple Current and Voltage Figure 11 and Figure 12 show the PoE and AUX input ripple current, respectively, under full load. In both cases, the input ripple current is attenuated to less than 10 mA pk-pk by the input filter. Horizontal Resolution: 50 µs/div. Trace 1: The PoE input current ripples (AC coupled). 20 mAV/div. Trace 2: The FFT of Trace 1. Horizontal 500 kHz/div. Vertical 5 mA/div Figure 11. PoE Input Current Ripples under Full Load Horizontal Resolution: 5 µs/div. Trace 1: The AUX input current ripples (AC coupled). 10 mA/div. Trace 2: The FFT of Trace 1 showing the peak value of the harmonics. Horizontal 500 kHz/div. Vertical 2.5 mA/div. Figure 12. AUX Input Current Ripple Under Full Load Figure 13 shows the output ripple voltage. The FFT of the output ripple voltage indicates that the ripple harmonics are below 15 mV pk-pk. SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 15 A Note on the Use of Common-Mode Choke www.ti.com Horizontal Resolution: 50 µs/div. Trace 1: The 3.3V output voltage ripples (AC coupled). 0.2V/div Trace 2: The FFT of Trace 1 showing the peak value of the harmonics. Horizontal 500 kHz/div. Vertical 5 mV/div Figure 13. Output Ripple Voltage under Full Load 23 A Note on the Use of Common-Mode Choke A location is reserved on the evaluation board for an optional input common mode filter. For some special applications that have very strict EMI requirements, the common mode filter consisting of the choke U6 and two Y capacitors CE12 and CE13 can be used. On the original evaluation board, these three components are not populated, and U6’s pads are shorted with bus wires. When a common mode filter is required, a Coilcraft D1882-AL or equivalent can be used for U6, along with a Syfer 1808JA250102MCTPY2 or equivalent for CE12 and CE13. 24 Bill of Materials Table 2. Part 1. PoE Circuit BOM (1) (1) 16 ITEM PART NUMBER DESCRIPTION VALUE BR1 CBR1-D020S DIODE BRIDGE, SMDIP, CENTRAL 1A, 200V BR2 CBR1-D020S DIODE BRIDGE, SMDIP, CENTRAL 1A, 200V CE1 C2012X7R1E474K CAPACITOR, CER, CC0805, TDK 0.47 µF, 25V CE2 NU CE3 NU CE4 C5750X7R2A475M CAPACITOR, CER, CC2220, TDK 4.7 µF, 100V CE6 C5750X7R2A475M CAPACITOR, CER, CC2220, TDK 4.7 µF, 100V CE6 EEV-HA2A220P CAPACITOR, AL ELEC, PANASONIC 22 µF, 100V CE7 C3216X5R0J226M CAPACITOR, CER, CC1206, TDK 22 µF, 6.3V CE8 C3216X5R0J226M CAPACITOR, CER, CC1206, TDK 22 µF, 6.3V CE9 C3216X5R0J226M CAPACITOR, CER, CC1206, TDK 22 µF, 6.3V CE10 C3216X5R0J226M CAPACITOR, CER, CC1206, TDK 22 µF, 6.3V CE11 C2012X7R1E474K CAPACITOR, CER, CC0805, TDK 0.47 µF, 25V CE12 NU Note: NU stands for Not Used, namely not populated. AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Bill of Materials www.ti.com Table 2. Part 1. PoE Circuit BOM (1) (continued) ITEM PART NUMBER CE13 NU DESCRIPTION VALUE CE14 NU CE15 C3216X5R0J226M CAPACITOR, CER, CC1206, TDK 22 µF, 6.3V CE16 EMVY6R3ADA331MF80G CAPACITOR, AL ELEC, CHEMI-ON 330 µF, 6.3V CE19 C2012X5R1C105K CAPACITOR, CER, CC0805, TDK 1.0 µF, 16V CE20 C2012X7R1E474K CAPACITOR, CER, CC0805, TDK 0.4 µF, 25V CE21 C0805C473K5RAC CAPACITOR, CER, CC0805, KEMET 0.047 µF, 50V CE22 NU CE23 C0805C102K5RAC CAPACITOR, CER, CC0805, KEMET 1000 pF, 50V CE25 C0805C104K5RAC CAPACITOR, CER, CC0805, KEMET 0.1 µF, 50V CE26 C0805C473K5RAC CAPACITOR, CER, CC0805, KEMET 0.047 µF, 50V 2200 pF, 2 kV CE27 NU CE28 C4532X7R3D222K CAPACITOR, CER, CC1812, TDK CE29 C3216X7R2A104K CAPACITOR, CER, CC1206, TDK 0.1 µF, 100V CE31 C0805C473K5RAC CAPACITOR, CER, CC0805, KEMET 0.047 µF, 50V DIODE, SMB, DIODE INC 3A, 100V CE30 NU DE1 S3BB-13 DE2 NU DE3 BAT54S DUAL SCHOTTKY, SOT-23, DIODE INC DE4 CMHD4448 DIODE, SOD123, CENTRAL 125 mA, 75V DE5 NU DE6 CMR1U-01M DIODE, SMA, CENTRAL 1A, 100V DE7 NU P1 PJ-102A JE4 NU POWER JACK JE5 3104-2-00-01-00-00-080 POST, MILL MAX JE6 3104-2-00-01-00-00-080 POST, MILL MAX JE7 NU LE1 DO3308P-682MLD SM INDUCTOR, COILCRAFT 6.8 µH LE3 DO3316T-331MLD SM INDUCTOR, COILCRAFT 0.33 µH LED1 SSL-LXA228GC-TR11 LED,GREEN, LUMEX TP1 NU TP2 NU TP3 5012K-ND TEST POINT, KEYSTONE TP4 5012K-ND TEST POINT, KEYSTONE TP7 5012K-ND TEST POINT, KEYSTONE TP8 5012K-ND TEST POINT, KEYSTONE TP12 NU Q1A SI7898DP Q1B NU Q2 MOSFET, N-CH, PowerPAK, VISHAY 150V, 4.8A BSC022N03SG MOSFET, N-CH, PowerPAK, INFINEON 30V, 50A QE5 SI2301 MOSFET, P-CH, SOT-23, VISHAY QE6 SI2301 MOSFET, P-CH, SOT-23, VISHAY RE1A CRCW12068R20J RESISTOR 8.20 Ohm RE1B CRCW12068R20J RESISTOR 8.20 Ohm RE1C CRCW12068R20J RESISTOR 8.20 Ohm RE1D CRCW12068R20J RESISTOR 8.20 Ohm SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 17 Bill of Materials www.ti.com Table 2. Part 1. PoE Circuit BOM (1) (continued) ITEM PART NUMBER DESCRIPTION VALUE RE2A CRCW12068R20J RESISTOR 8.20 Ohm RE2B CRCW12068R20J RESISTOR 8.20 Ohm RE2C CRCW12068R20J RESISTOR 8.20 Ohm RE2D CRCW12068R20J RESISTOR 8.20 Ohm RE3 CRCW080520R0F RESISTOR 20 Ohm RE4 NU RE5 CRCW08053321F RESISTOR 3.32 kΩ RE6 CRCW080524R9J RESISTOR 24.9 Ohm RE7 CRCW080510R0F RESISTOR 10 Ohm RE8 NU RE9 CRCW08051000F RESISTOR 100 Ohm RE10 NU RE11 NU RE12 CRCW08052432F RESISTOR 24.3 kΩ RE13 CRCW08054991F RESISTOR 4.99 kΩ RE14 CRCW12060R47F RESISTOR 0.47 Ohm RE15 CRCW12060R47F RESISTOR 0.47 Ohm RE16 NU RE17 CRCW08055900F RESISTOR 1 kΩ RE18 CRCW08051472F RESISTOR 14.7 kΩ RE19 NU RE20 CRCW08051001F RESISTOR 1 kΩ RE21 CRCW08052102F RESISTOR 21.0 kΩ RE22 NU RE23 CRCW08051582F RESISTOR 15.8 kΩ RE25 CRCW12060R47F RESISTOR 0.47 Ohm RE26 NU RE28 CRCW08050R0J RESISTOR 332 Ohm RE29 CRCW12062492F RESISTOR 24.9 kΩ RE34 CRCW08050R0J RESISTOR 0 Ohm U5 LM5072-80 POE PI AND PWM CTRL, NATIONAL U6 SHORT LEADS U7 FA2677-AL XFMR, FLYBACK, EFD20, COILCRAFT U11 FA2659-AL PULSE XFMR, 1:1, COILCRAFT UE2 PS2811-1-M OPTO-COUPLER, NEC UE3 LMV431A REFERENCE, SOT23-3, NATIONAL ZE1 CMZ5944B ZENER, 62V, SMA, CENTRAL ZE2 SMAJ58A TVS, 58V, SMA, DIODE INC ZE3 CMPZ4619 ZENER, 3.0V, SOT23-3 CENTRAL Table 3. Part 2. PHYTER BOM (1) ITEM (1) 18 DESCRIPTION VALUE C1 PART NUMBER CAPACITOR, TAN, CC7343 33 µF, 35V C2 CAPACITOR, TAN, CC7343 33 µF, 35V C3 CAPACITOR, CER, C0805, KEMET 33 pF, 50V C4 CAPACITOR, CER, C0805, KEMET 33 pF, 50V Note: NU stands for Not Used, namely not populated. AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Bill of Materials www.ti.com Table 3. Part 2. PHYTER BOM (1) (continued) ITEM DESCRIPTION VALUE C5 PART NUMBER CAPACITOR, TAN, CC7343 10 µF, 35V C6 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C7 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C8 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C9 CAPACITOR, TAN, CC3528 68 µF, 6V C10 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C11 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C12 CAPACITOR, TAN, CC3528 33 µF, 6V C13 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C14 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C15 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C16 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C17 CAPACITOR, TAN, CC7343 10 µF, 35V C18 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C20 CAPACITOR, TAN, CC7343 10 µF, 35V C21 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C22 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C23 CAPACITOR, CER, CC0603, KEMET 0.1 µF, 50V C49 CAPACITOR, CER, CC0603, KEMET, -E Board ONLY 8 pF, 50V C50 CAPACITOR, CER, CC0603, KEMET, -E Board ONLY 8 pF, 50V C53 CAPACITOR, CER, CC0603, KEMET, -E Board ONLY 8 pF, 50V C54 CAPACITOR, CER, CC0603, KEMET, -E Board ONLY 8 pF, 50V DS1 LTM673-R1S2-35 LED GREEN, OSRAM DS2 LTM673-R1S2-35 LED GREEN, OSRAM DS3 LTM673-R1S2-35 LED GREEN, OSRAM DS4 LTM673-R1S2-35 LED GREEN, OSRAM J1 CN MII-MALE CONNECTOR, MII J2 TEST POINT, KEYSTONE J3 TEST POINT, KEYSTONE J4 TEST POINT, KEYSTONE J5 TEST POINT, KEYSTONE J6 TEST POINT, KEYSTONE J7 TEST POINT, KEYSTONE J8 TEST POINT, KEYSTONE J9 TEST POINT, KEYSTONE J10 NU J11 NU J13 CN-PHONE8P8C-RA-SHLD J15 CONNECTOR RJ45, -E BOARD ONLY TEST POINT, KEYSTONE J16 TEST POINT, KEYSTONE J18 NU R1 CRCW060333R0J RESISTOR 33 Ohm R2 CRCW060333R0J RESISTOR 33 Ohm R3 CRCW060333R0J RESISTOR 33 Ohm R4 CRCW060333R0J RESISTOR 33 Ohm SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 19 Bill of Materials www.ti.com Table 3. Part 2. PHYTER BOM (1) (continued) 20 ITEM PART NUMBER DESCRIPTION VALUE R5 CRCW060333R0J RESISTOR 33 Ohm R6 CRCW060333R0J RESISTOR 33 Ohm R7 CRCW06032201F RESISTOR 2.2 kΩ R8 CRCW06032201F RESISTOR 2.2 kΩ R9 CRCW06032201F RESISTOR 2.2 kΩ R10 CRCW06032201F RESISTOR 2.2 kΩ R11 CRCW06032201F RESISTOR 2.2 kΩ R12 CRCW06032201F RESISTOR 2.2 kΩ R13 CRCW06032201F RESISTOR 2.2 kΩ R14 CRCW06032201F RESISTOR 2.2 kΩ R15 CRCW08050R0J RESISTOR 0 Ohm R16 CRCW06031002F RESISTOR 10 kΩ R17 CRCW060333R0J RESISTOR 33 Ohm R18 CRCW060333R0J RESISTOR 33 Ohm R19 CRCW060333R0J RESISTOR 33 Ohm R20 CRCW060333R0J RESISTOR 33 Ohm R21 CRCW060333R0J RESISTOR 33 Ohm R22 CRCW060333R0J RESISTOR 33 Ohm R23 CRCW060333R0J RESISTOR 33 Ohm R24 CRCW060333R0J RESISTOR 33 Ohm R25 CRCW060333R0J RESISTOR 33 Ohm R26 CRCW06032200F RESISTOR 220 Ohm R28 CRCW08051501F RESISTOR 1.5 kΩ R29 CRCW06032201F RESISTOR 2.2 kΩ R30 CRCW060324871F RESISTOR 4.87 kΩ R31 CRCW06032201F RESISTOR 2.2 kΩ R32 CRCW06032201F RESISTOR 2.2 kΩ R33 CRCW060349R9J RESISTOR 49.9 Ohm R34 CRCW060349R9J RESISTOR 49.9 Ohm R35 CRCW060349R9J RESISTOR 49.9 Ohm R36 CRCW060349R9J RESISTOR 49.9 Ohm R37 CRCW06032200F RESISTOR 220 Ohm R39 CRCW06032200F RESISTOR 220 Ohm R41 CRCW06032200F RESISTOR 220 Ohm R42 CRCW12060R0J RESISTOR 0 Ohm R43 CRCW12060R0J RESISTOR 0 Ohm R44 CRCW12060R0J RESISTOR 0 Ohm R45 CRCW12060R0J RESISTOR 0 Ohm R50 CRCW12060R0J RESISTOR 0 Ohm R51 CRCW12060R0J RESISTOR 0 Ohm R52 CRCW12060R0J RESISTOR 0 Ohm R53 CRCW12060R0J RESISTOR 0 Ohm R54 CRCW12060R0J RESISTOR 0 Ohm R55 CRCW12060R0J RESISTOR 0 Ohm R56 CRCW12060R0J RESISTOR 0 Ohm R57 CRCW12060R0J RESISTOR 0 Ohm U1 DP83848-IVV PHY TRANSCEIVER, NATIONAL AN-1521 POEPHYTEREV-I / -E Evaluation Board SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback Copyright © 2006–2013, Texas Instruments Incorporated Bill of Materials www.ti.com Table 3. Part 2. PHYTER BOM (1) (continued) ITEM PART NUMBER DESCRIPTION U4 ETH1-230LD TRANSFORMER, ETHERNET, COILCRAFT, -E BOARD ONLY U8 NU U9 NU U10 NU UE13 0838-1X1T-W6 CONNECTOR, INTEGRATED WITH ETHERNET TRANSFORMER, BEL STEWARD, -I BOARD ONLY Y1 FOXSLF/250F-20 CRYSTAL, HC49-US, SNOA476C – October 2006 – Revised April 2013 Submit Documentation Feedback VALUE 25 MHz AN-1521 POEPHYTEREV-I / -E Evaluation Board Copyright © 2006–2013, Texas Instruments Incorporated 21 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. 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