19-2991; Rev 2; 2/06 KIT ATION EVALU LE B A IL A AV IEEE 802.3af PD Interface Controller For Power-Over-Ethernet Features The MAX5940A/MAX5940B/MAX5940C/MAX5940D provide complete interface function for a powered device (PD) to comply with the IEEE 802.3af standard in a power-over-ethernet system. MAX5940A/MAX5940B/ MAX5940C/MAX5940D provide the PD with a detection signature, a classification signature, and an integrated isolation switch with programmable inrush current control. These devices also feature power-mode undervoltage lockout (UVLO) with wide hysteresis and powergood outputs. The MAX5940A/MAX5940B are available with an absolute maximum rating of 80V and the MAX5940C/MAX5940D are rated for an absolute maximum rating of 90V. An integrated MOSFET provides PD isolation during detection and classification. All devices guarantee a leakage current offset of less than 10A during the detection phase. A programmable current limit prevents high inrush current during power-on. The device features powermode UVLO with wide hysteresis and long deglitch time to compensate for twisted-pair cable resistive drop and to assure glitch-free transition between detection, classification, and power-on/-off phases. The MAX5940A/MAX5940C provide an active-high (PGOOD) open-drain output and a fixed UVLO threshold. The MAX5940B/MAX5940D provide both active-high (PGOOD) and active-low (PGOOD) outputs and have an adjustable UVLO threshold with the default value compliant to the 802.3af standard. All devices are designed to work with or without an external diode bridge. Fully Integrated IEEE 802.3af-Compliant PD Interface PD Detection and Programmable Classification Signatures Less than 10A Leakage Current Offset During Detection Integrated MOSFET For Isolation and Inrush Current Limiting 90V Absolute Maximum Rating (MAX5940C/MAX5940D) Gate Output Allows External Control of the Internal Isolation MOSFET Programmable Inrush Current Control Programmable Undervoltage Lockout (MAX5940B/MAX5940D Only) Wide UVLO Hysteresis Accommodates TwistedPair Cable Voltage Drop PGOOD/PGOOD Outputs to Enable Downstream DC-DC Converters -40C to +85C Operating Temperature Range Ordering Information PINPACKAGE PART TEMP RANGE The MAX5940A/MAX5940B/MAX5940C/MAX5940D are available in 8-pin SO packages and are rated over the extended temperature range of -40C to +85C. MAX5940AESA -40C to +85C 8 SO Fixed MAX5940BESA -40C to +85C 8 SO Adjustable MAX5940CESA -40C to +85C 8 SO Fixed Applications MAX5940DESA -40C to +85C 8 SO Adjustable IP Phones Security Cameras Wireless Access Nodes IEEE 802.3af Power Devices UVLO Pin Configurations appear at end of data sheet. Computer Telephony Typical Operating Circuits D1* DC-DC CONVERTER GND V+ GND 60V 68nF RDISC 25.5k RCL D2* -48V 2 COUT MAX5014 GND 3 VREG RCLASS GATE 4 VEE *OPTIONAL. 8 SS_SHDN MAX5940A MAX5940C PGOOD 6 OUT LOAD 5 CGATE Typical Operating Circuits continued at end of data sheet. ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at 1-888-629-4642, or visit Maxim's website at www.maxim-ic.com. 1 MAX5940A/MAX5940B/MAX5940C/MAX5940D General Description MAX5940A/MAX5940B/MAX5940C/MAX5940D IEEE 802.3af PD Interface Controller For Power-Over-Ethernet ABSOLUTE MAXIMUM RATINGS GND, RCLASS to VEE .....................................................70mA UVLO, PGOOD, PGOOD to VEE .....................................20mA GATE to VEE ....................................................................80mA Continuous Power Dissipation (TA = +70C) 8-Pin SO (derate 5.9mW/C above +70C)..................470mW Operating Temperature Range ...........................-40C to +85C Storage Temperature Range .............................-65C to +150C Junction Temperature ......................................................+150C Lead Temperature (soldering, 10s) ................................+300C (All voltages are referenced to VEE, unless otherwise noted.) GND (MAX5940A/MAX5940B) ...............................-0.3V to +80V GND (MAX5940C/MAX5940D)...............................-0.3V to +90V OUT, PGOOD ...........................................-0.3V to (GND + 0.3V) RCLASS, GATE ......................................................-0.3V to +12V UVLO ........................................................................-0.3V to +8V PGOOD to OUT.........................................-0.3V to (GND + 0.3V) Maximum Input/Output Current (continuous) OUT to VEE ...................................................................500mA Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (VIN = (GND - VEE) = 48V, GATE = PGOOD = PGOOD = OUT = OPEN, UVLO = VEE, TA = -40C to +85C, unless otherwise noted. Typical values are at TA = +25C. All voltages are referenced to VEE, unless otherwise noted.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 10 A DETECTION MODE Input Offset Current (Note 2) Effective Differential Input Resistance (Note 3) IOFFSET dR VIN = 1.4V to 10.1V VIN = 1.4V up to 10.1V with 1V step, OUT = PGOOD = GND 550 VIN rising 20.8 k CLASSIFICATION MODE Classification Current Turn-Off Threshold (Note 4) VTH,CLSS Class 0, RCL = 10k Classification Current (Notes 5, 6) ICLASS VIN = 12.6V to Class 1, RCL = 732 20V, RDISC = Class 2, RCL = 392 25.5k Class 3, RCL = 255 Class 4, RCL = 178 21.8 22.5 0 2 9.17 11.83 17.29 19.71 26.45 29.55 36.6 41.4 V mA POWER MODE Operating Supply Voltage VIN VIN = (GND - VEE) Operating Supply Current IIN Measure at GND, not including RDISC 1 35.4 36.6 MAX5940B/MAX5940D, UVLO = VEE 37.4 38.6 39.9 VIN increasing Default Power Turn-Off Voltage VUVLO, OFF VIN decreasing, UVLO = VEE for MAX5940B/MAX5940D 30 MAX5940A/MAX5940C 4.2 UVLO MAX5940B/MAX5940D, UVLO = VEE 7.4 VIN,EX Set UVLO externally (MAX5940B/ MAX5940D only) (Note 7) 12 External UVLO Programming Range UVLO External Reference Voltage VREF, UVLO UVLO External Reference Voltage Hysteresis HYST UVLO Bias Current IUVLO 2 mA 0.4 34.3 VUVLO, ON VHYST, V MAX5940A/MAX5940C Default Power Turn-On Voltage Default Power Turn-On/Off Hysteresis 67 V V V 67 V 2.400 2.460 2.522 V Ratio to VREF,UVLO 19.2 20 20.9 % UVLO = 2.460V -1.5 +1.5 A _______________________________________________________________________________________ IEEE 802.3af PD Interface Controller For Power-Over-Ethernet (VIN = (GND - VEE) = 48V, GATE = PGOOD = PGOOD = OUT = OPEN, UVLO = VEE, TA = -40C to +85C, unless otherwise noted. Typical values are at TA = +25C. All voltages are referenced to VEE, unless otherwise noted.) (Note 1) PARAMETER UVLO Input Ground Sense Threshold (Note 8) SYMBOL VTH,G,UVLO UVLO Input Ground Sense Glitch Rejection Power Turn-Off Voltage, Undervoltage Lockout Deglitch Time (Note 9) Isolation Switch N-Channel MOSFET On-Resistance Isolation Switch N-Channel MOSFET Off-Threshold Voltage GATE Pulldown Switch Resistance GATE Charging Current GATE High Voltage PGOOD, PGOOD Assertion VOUT Threshold CONDITIONS MIN 50 UVLO = VEE tOFF_DLY RON VGSTH VIN, VUVLO falling Output current = 300mA, VGATE = 6V, measured between OUT and VEE PGOOD, PGOOD Output Low Voltage (Note 11) mV s TA = +25C (Note 10) 0.6 1.1 TA = +85C 0.8 1.5 OUT = GND, VGATE - VEE, output current < 1A 0.5 V IG VGATE = 2V 5 VGATE IGATE = 1A 5.59 VOUT - VEE, |VOUT - VEE| decreasing, VGATE = 5.75V 1.16 1.23 VOLDCDC 440 ms Power-off mode, VIN = 12V, UVLO = VEE for MAX5940B VGSEN UNITS 0.32 RG VOUTEN MAX 7 (GATE - VEE) increasing, OUT = VEE Hysteresis ISINK = 2mA; for PGOOD, OUT (GND - 5V) 80 10 15 A 5.76 5.93 V 1.31 V 38 Hysteresis PGOOD, PGOOD Assertion VGATE Threshold TYP 70 4.62 4.76 mV 4.91 80 V mV 0.4 V PGOOD Leakage Current (Note 11) GATE = high, GND - VOUT = 67V 1 A PGOOD Leakage Current (Note 11) GATE = VEE, PGOOD - VEE = 67V 1 A Note 1: All min/max limits are production tested at +85C. Limits at +25C and -40C are guaranteed by design. Note 2: The input offset current is illustrated in Figure 1. Note 3: Effective differential input resistance is defined as the differential resistance between GND and VEE without any external resistance. See Figure 1. Note 4: Classification current is turned off whenever the IC is in power mode. Note 5: See Table 2 in the PD Classification Mode section. RDISC and RCL must be 1%, 100ppm or better. ICLASS includes the IC bias current and the current drawn by RDISC. Note 6: See the Thermal Dissipation section for details. Note 7: When UVLO is connected to the midpoint of an external resistor-divider with a series resistance of 25.5k (1%), the turnon threshold set-point for the power mode is defined by the external resistor-divider. Make sure the voltage on the UVLO pin does not exceed its maximum rating of 8V when VIN is at the maximum voltage (MAX5940B only). Note 8: When the UVLO input voltage is below VTH,G,UVLO, the MAX5940B sets the UVLO threshold internally. Note 9: An input voltage or VUVLO glitch below their respective thresholds shorter than or equal to t OFF_DLY does not cause the MAX5940A/MAX5940B/MAX5940C/MAX5940D to exit power-on mode (as long as the input voltage remains above an operable voltage level of 12V). Note 10: Guaranteed by design. Note 11: PGOOD references to OUT while PGOOD references to VEE. _______________________________________________________________________________________ 3 MAX5940A/MAX5940B/MAX5940C/MAX5940D ELECTRICAL CHARACTERISTICS (continued) IIN dRi 1V (VINi + 1 - VINi) = (IINi + 1 - IINi) (IINi + 1 - IINi) IOFFSET IINi - VINi dRi IINi + 1 dRi IINi IOFFSET VINi 1V VINi + 1 VIN Figure1. Effective Differential Input Resistance/Offset Current Typical Operating Characteristics (VIN = (GND - VEE) = 48V, GATE = PGOOD = PGOOD = OUT = OPEN, UVLO = VEE (MAX5940B), TA = -40C to +85C. Typical values are at TA = +25C. All voltages are referenced to VEE, unless otherwise noted.) 0.3 IIN + IRDISC 0.2 0.1 CLASS 4 30 CLASS 3 20 CLASS 2 CLASS 1 10 CLASS 0 0 2 4 6 8 0 5 10 15 20 25 3.0 2.5 2.0 1.5 1.0 0.5 0 30 0 2 4 6 8 10 INPUT VOLTAGE (V) INPUT VOLTAGE (V) INPUT VOLTAGE (V) INPUT OFFSET CURRENT vs. INPUT VOLTAGE NORMALIZED UVLO vs. TEMPERATURE PGOOD OUTPUT LOW VOLTAGE vs. CURRENT 1.006 NORMALIZED UVLO -1.0 -1.5 -2.0 -2.5 200 1.004 1.002 1.000 0.998 150 100 0.996 50 0.994 -3.0 250 VPGOOD (mV) -0.5 UVLO = VEE 1.008 12 MAX5940A/B toc06 1.010 MAX5940A/B toc04 0 0.992 -3.5 0 0.990 1 3 5 7 INPUT VOLTAGE (V) 4 0 10 MAX5940A/B toc05 0 3.5 MAX5940A/B toc03 40 EFFECTIVE DIFFERENTIAL INPUT RESISTANCE (M) 0.4 50 MAX5940A/B toc02 DETECTION CURRENT (mA) RDISC = 25.5k CLASSIFICATION CURRENT (mA) MAX5940A/B toc01 0.5 EFFECTIVE DIFFERENTIAL INPUT RESISTANCE vs. INPUT VOLTAGE CLASSIFICATION CURRENT vs. INPUT VOLTAGE DETECTION CURRENT vs. INPUT VOLTAGE INPUT OFFSET CURRENT (A) MAX5940A/MAX5940B/MAX5940C/MAX5940D IEEE 802.3af PD Interface Controller For Power-Over-Ethernet 9 11 -40 -15 10 35 TEMPERATURE (C) 60 85 0 5 10 ISINK (mA) _______________________________________________________________________________________ 15 20 IEEE 802.3af PD Interface Controller For Power-Over-Ethernet (VIN = (GND - VEE) = 48V, GATE = PGOOD = PGOOD = OUT = OPEN, UVLO = VEE (MAX5940B), TA = -40C to +85C. Typical values are at TA = +25C. All voltages are referenced to VEE, unless otherwise noted.) OUT LEAKAGE CURRENT vs. TEMPERATURE PGOOD OUTPUT LOW VOLTAGE vs. CURRENT VPGOOD (mV) 240 160 80 MAX5940A/B toc08 320 INRUSH CURRENT CONTROL (VIN = 12V) MAX5940A/B toc09 20 VOUT = 67V OUT LEAKAGE CURRENT (nA) MAX5940A/B toc07 400 16 VGATE 5V/div 12 IINRUSH 100mA/div 8 VOUT TO VEE 10V/div 4 PGOOD 10V/div 0 0 0 5 10 15 20 -40 -15 10 35 60 1ms/div 85 TEMPERATURE (C) ISINK (mA) INRUSH CURRENT CONTROL (VIN = 48V) INRUSH CURRENT CONTROL (VIN = 67V) MAX5940A/B toc10 MAX5940A/B toc11 VGATE 5V/div VGATE 5V/div IINRUSH 100mA/div IINRUSH 100mA/div VOUT TO VEE 50V/div VOUT TO VEE 50V/div PGOOD PGOOD 50V/div 50V/div 2ms/div 2ms/div _______________________________________________________________________________________ 5 MAX5940A/MAX5940B/MAX5940C/MAX5940D Typical Operating Characteristics (continued) MAX5940A/MAX5940B/MAX5940C/MAX5940D IEEE 802.3af PD Interface Controller For Power-Over-Ethernet Pin Description PIN MAX5940A/ MAX5940B/ MAX5940C MAX5940D 1, 7 -- NAME N.C. -- 1 UVLO 2 2 RCLASS FUNCTION No Connection. Not internally connected. Undervoltage Lockout Programming Input for Power Mode. When UVLO is above its threshold, the device enters power mode. Connect UVLO to VEE to use the default undervoltage lockout threshold. Connect UVLO to an external resistor-divider to define a threshold externally. The series resistance value of the external resistors must add to 25.5k (1%) and replaces the detection resistor. To keep the device in undervoltage lockout, pull UVLO to between VTH,G,UVLO and VREF,UVLO. Classification Setting. Add a resistor from RCLASS to VEE to set a PD class (see Tables 1 and 2). Gate of Internal N-Channel Power MOSFET. GATE sources 10A when the device enters power mode. Connect an external 100V ceramic capacitor (CGATE) from GATE to OUT to program the inrush current. Pull GATE to VEE to turn off the internal MOSFET. The detection and classification functions operate normally when GATE is pulled to VEE. 3 3 GATE 4 4 VEE Negative Input Power. Source of the integrated isolation N-channel power MOSFET. Connect VEE to -48V. 5 5 OUT Output Voltage. Drain of the integrated isolation N-channel power MOSFET. 6 6 PGOOD Power-Good Indicator Output, Active-High, Open-Drain. PGOOD is referenced to OUT. PGOOD goes high impedance when VOUT is within 1.2V of VEE and when GATE is 5V above VEE. Otherwise, PGOOD is pulled to OUT (given that VOUT is at least 5V below GND). Connect PGOOD to the ON pin of a downstream DC-DC converter. Power-Good Indicator Output, Active-Low, Open-Drain. PGOOD is referenced to VEE. PGOOD is pulled to VEE when VOUT is within 1.2V of VEE and when GATE is 5V above VEE. Otherwise, PGOOD goes high impedance. Connect PGOOD to the ON pin of a downstream DC-DC converter. -- 7 PGOOD 8 8 GND Ground. GND is the positive input terminal. Detailed Description Operating Modes The PD front-end section of the MAX5940_ operates in 3 different modes, PD detection signature, PD classification, and PD power, depending on its input voltage (VIN = GND - VEE). All voltage thresholds are designed to operate with or without the optional diode bridge while still complying with the IEEE 802.3af standard (see Figure 4). Detection Mode (1.4V VIN 10.1V) In detection mode, the power source equipment (PSE) applies two voltages on VIN in the range of 1.4V to 10.1V 6 (1V step minimum), and then records the current measurements at the two points. The PSE then computes V/I to ensure the presence of the 25.5k signature resistor. In this mode, most of the MAX5940_ internal circuitry is off and the offset current is less than 10A. If the voltage applied to the PD is reversed, install protection diodes on the input terminal to prevent internal damage to the MAX5940_ (see the Typical Application Circuits). Since the PSE uses a slope technique (V/I) to calculate the signature resistance, the DC offset due to the protection diodes is subtracted and does not affect the detection process. _______________________________________________________________________________________ IEEE 802.3af PD Interface Controller For Power-Over-Ethernet CLASS USAGE RCL () MAXIMUM POWER USED BY PD (W) 0 Default 10k 0.44 to 12.95 1 Optional 732 0.44 to 3.84 2 Optional 392 3.84 to 6.49 3 Optional 255 6.49 to 12.95 4 Not Allowed 178 Reserved* *Class 4 reserved for future use. Table 2. Setting Classification Current CLASS CURRENT SEEN AT VIN (mA) IEEE 802.3af PD CLASSIFICATION CURRENT SPECIFICATION (mA) CLASS RCL () VIN* (V) MIN MAX MIN 0 10k 12.6 to 20 0 2 0 4 1 732 12.6 to 20 9.17 11.83 9 12 2 392 12.6 to 20 17.29 19.71 17 20 3 255 12.6 to 20 26.45 29.55 26 30 4 178 12.6 to 20 36.6 41.4 36 44 MAX *VIN is measured across the MAX5940 input pins, which does not include the diode bridge voltage drop. Classification Mode (12.6V VIN 20V) In the classification mode, the PSE classifies the PD based on the power consumption required by the PD. This allows the PSE to efficiently manage power distribution. The IEEE 802.3af standard defines five different classes as shown in Table 1. An external resistor (R CL) connected from RCLASS to VEE sets the classification current. The PSE determines the class of a PD by applying a voltage at the PD input and measures the current sourced out of the PSE. When the PSE applies a voltage between 12.6V and 20V, the MAX5940_ exhibit a current characteristic with values indicated in Table 2. The PSE uses the classification current information to classify the power requirement of the PD. The classification current includes the current drawn by the 25.5k detection signature resistor and the supply current of the MAX5940_ so the total current drawn by the PD is within the IEEE 802.3af standard figures. The classification current is turned off whenever the device is in power mode. Power Mode During power mode, when VIN rises above the undervoltage lockout threshold (VUVLO,ON), the MAX5940_ gradually turn on the internal N-channel MOSFET Q1 (see Figure 2). The MAX5940_ charge the gate of Q1 with a constant current source (10A, typ). The drainto-gate capacitance of Q1 limits the voltage rise rate at the drain of the MOSFET, thereby limiting the inrush current. To reduce the inrush current, add external drain-to-gate capacitance (see the Inrush Current Limit section). When the drain of Q1 is within 1.2V of its source voltage and its gate-to-source voltage is above 5V, the MAX5940_ asserts the PGOOD/PGOOD outputs. The MAX5940_ have a wide UVLO hysteresis and turn-off deglitch time to compensate for the high impedance of the twisted-pair cable. Undervoltage Lockout The MAX5940_ operate up to a 67V supply voltage with a default UVLO turn-on (V UVLO,ON ) set at 35V (MAX5940A/MAX5940C) or 39V (MAX5940B/MAX5940D) and a UVLO turn-off (V UVLO,OFF ) set at 30V. The MAX5940B/MAX5940D have an adjustable UVLO threshold using a resistor-divider connected to UVLO (see Figure 3). When the input voltage is above the UVLO threshold, the IC is in power mode and the MOSFET is on. When the input voltage goes below the UVLO threshold for more than tOFF_DLY, the MOSFET turns off. _______________________________________________________________________________________ 7 MAX5940A/MAX5940B/MAX5940C/MAX5940D Table 1. PD Power Classification/RCL Selection MAX5940A/MAX5940B/MAX5940C/MAX5940D IEEE 802.3af PD Interface Controller For Power-Over-Ethernet GND 2.46V UVLO REF EN GND CLASSIFICATION 6.8V RCLASS R1 (PGOOD) MAX5940B MAX5940D Q4 R2 20% R3 VGATE 1.2V, REF EN (UVLO) PGOOD 5V, REF Q3 OUT Q2 200mV GATE Q1 VEE ( ) MAX5940B. Figure 2. Block Diagram To adjust the UVLO threshold (MAX5940B/MAX5940D only), connect an external resistor-divider from GND to UVLO and from UVLO to VEE. Use the following equations to calculate R1 and R2 for a desired UVLO threshold: R2 = 25.5k x VIN = 12V TO 67V VREF,UVLO GND VIN,EX R1 R1 = 25.5k - R2 where VIN,EX is the desired UVLO threshold. Since the resistor-divider replaces the 25.5k PD detection resistor, ensure that the sum of R1 and R2 equals 25.5k 1%. When using the external resistor-divider, the MAX5940B/MAX5940D has an external reference voltage hysteresis of 20% (typ). When UVLO is programmed externally, the turn-off threshold is 80% (typ) of the new UVLO threshold. UVLO MAX5940B MAX5940D R2 VEE Figure 3. Setting Undervoltage Lockout with an External Resistor-Divider 8 _______________________________________________________________________________________ IEEE 802.3af PD Interface Controller For Power-Over-Ethernet IINRUSH = IG x COUT CGATE PGOOD/PGOOD Outputs (MAX5940A/MAX5940C only) PGOOD is an open-drain, active-high logic output. PGOOD goes high impedance when VOUT is within 1.2V of VEE and when GATE is 5V above VEE. Otherwise, PGOOD is pulled to VOUT (given that VOUT is at least 5V below GND). Connect PGOOD to the ON pin of a downstream DC-DC converter. Connect a 100k pullup resistor from PGOOD to GND if needed. (MAX5940B/MAX5940D only) PGOOD is an open-drain, active-low logic output. PGOOD is pulled to VEE when VOUT is within 1.2V of VEE and when GATE is 5V above VEE. Otherwise, PGOOD goes high impedance. Connect PGOOD to the ON pin of a downstream DC-DC converter. Connect a 100k pullup resistor from PGOOD to GND if needed. Thermal Dissipation During classification mode, if the PSE applies the maximum DC voltage, the maximum voltage drop from GND to VRCLASS will be 13V. If the maximum classification current of 42mA flows through the MAX5940_, then the maximum DC power dissipation will be 546mW, which is slightly higher than the maximum DC power dissipation of the IC at maximum operating temperature. However, according to the IEEE 802.3af standard, the duration of the classification mode is limited to 75ms (max). The MAX5940_ handle the maximum classification power dissipation for the maximum duration time without sustaining any internal damage. If the PSE violates the IEEE 802.3af standard by exceeding the 75ms maximum classification duration, it may cause internal damage to the IC. _______________________________________________________________________________________ 9 MAX5940A/MAX5940B/MAX5940C/MAX5940D Inrush Current Limit The MAX5940_ charge the gate of the internal MOSFET with a constant current source (10A, typ). The drainto-gate capacitance of the MOSFET limits the voltage rise rate at the drain, thereby limiting the inrush current. Add an external capacitor from GATE to OUT to further reduce the inrush current. Use the following equation to calculate the inrush current: IEEE 802.3af PD Interface Controller For Power-Over-Ethernet MAX5940A/MAX5940B/MAX5940C/MAX5940D Typical Application Circuits Application Circuit 1 POWER-OVER SIGNAL PAIRS VREG RX 3 6 1 PHY 2 GND + + - - RJ-45 4 TX 5 7 -48V 8 POWER-OVER SPAIR PAIRS DC-DC CONVERTER GND V+ RDISC 25.5k R1* 1 60V 68nF 2 UVLO RCLASS GND MAX5940B MAX5940D PGOOD 8 MAX5014 COUT 7 GND SS_SHDN R2* -48V RCL 3 GATE 4 VEE PGOOD OUT 6 5 CGATE *R1 AND R2 ARE OPTIONAL AND WHEN USED, THEY MUST TOTAL 25.5k AND REPLACE THE 25.5k RESISTOR. Figure 4. PD with Power-Over-Ethernet (Power is Provided by Either the Signal Pairs or the Spare Pairs) 10 VREG ______________________________________________________________________________________ LOAD IEEE 802.3af PD Interface Controller For Power-Over-Ethernet GATE is pulled low to pinch off the power-over-ethernet. The wall adapter power pollutes the discovery signature, preventing PSE from detecting this PD. Application Circuit 2 Diode D1 prevents the power-over-ethernet to back drive the wall adapter. Whenever the wall adapter power is greater than (VD3 + approximately 2V), the DC-DC CONVERTER V+ GND 1 RDISC 25.5k 60V 68nF 2 UVLO GND MAX5940B MAX5940D RCLASS PGOOD 8 COUT 7 MAX5014 PGOOD GND SS_SHDN RCL 3 GATE PGOOD 4 VEE -48V OUT VEE WALL ADAPTER SUPPLY VREG 6 LOAD 5 CGATE GATE D1 D3 100k PGOOD PS2701A-1 GATE VEE CMPT3904 2.0k CMPT3904 Figure 5. Adding Wall Adapter Input Supply (Wall Adapter Supply Takes Precedence Over Power-Over-Ethernet) ______________________________________________________________________________________ 11 MAX5940A/MAX5940B/MAX5940C/MAX5940D Typical Application Circuits (continued) MAX5940A/MAX5940B/MAX5940C/MAX5940D IEEE 802.3af PD Interface Controller For Power-Over-Ethernet Typical Application Circuits (continued) Application Circuit 3 R4 provides the 10mA minimum power maintenance signature to keep the power-over-ethernet from disconnecting. D2 prevents the wall adapter power from polluting the discovery and classification signatures. The optional DC-DC CONVERTER D2 V+ GND 1 RDISC 25.5k 60V 68nF 2 UVLO GND VREG R4 4k 2W MAX5940B MAX5940D RCLASS 8 PGOOD MAX5014 COUT 7 GND RCL 3 GATE 4 VEE -48V PGOOD OUT SS_SHDN LOAD 6 5 CGATE WALL ADAPTER SUPPLY D1 Figure 6. Adding Wall Adapter Input Supply (Wall Adapter Supply And Power-Over-Ethernet Co-Exist, the One with Higher Voltage Provides Power To The Load) 12 ______________________________________________________________________________________ IEEE 802.3af PD Interface Controller For Power-Over-Ethernet Application Circuit 4 fication signatures. If the power-over-ethernet comes up first, it powers the load until taken over by a wall adapter with higher output voltage. If the wall adapter supply comes up first, it provides power to the load and pollute the discovery and classi- DC-DC CONVERTER V+ GND 1 RDISC 25.5k 60V 68nF 2 UVLO GND MAX5940B MAX5940D RCLASS PGOOD 8 VREG COUT MAX5014 7 GND SS_SHDN RCL 3 GATE 4 VEE -48V PGOOD OUT LOAD 6 5 CGATE WALL ADAPTER SUPPLY D1 Figure 7. Adding Wall Adapter Input Supply (the One with Higher Voltage Provides Power to the Load) ______________________________________________________________________________________ 13 MAX5940A/MAX5940B/MAX5940C/MAX5940D Typical Application Circuits (continued) IEEE 802.3af PD Interface Controller For Power-Over-Ethernet MAX5940A/MAX5940B/MAX5940C/MAX5940D Typical Operating Circuits (continued) D1* DC-DC CONVERTER GND RDISC 25.5k V+ R1** 1 60V 68nF 2 RCL R2** D2* 3 UVLO RCLASS GATE 4 -48V VEE GND PGOOD 8 MAX5014 COUT 7 GND SS_SHDN VREG LOAD MAX5940B 6 PGOOD MAX5940D OUT 5 CGATE *OPTIONAL. **R1 AND R2 ARE OPTIONAL AND WHEN USED, THEY MUST TOTAL 25.5k AND REPLACE THE 25.5k RESISTOR. Pin Configurations Chip Information TRANSISTOR COUNT: 3,643 PROCESS: BiCMOS TOP VIEW N.C. 1 RCLASS 2 GATE 3 MAX5940A MAX5940C VEE 4 8 GND 7 N.C. 6 PGOOD 5 OUT 8 GND 7 PGOOD 6 PGOOD 5 OUT SO UVLO 1 RCLASS 2 GATE 3 MAX5940B MAX5940D VEE 4 SO 14 ______________________________________________________________________________________ IEEE 802.3af PD Interface Controller For Power-Over-Ethernet N E H INCHES MILLIMETERS MAX MIN 0.069 0.053 0.010 0.004 0.014 0.019 0.007 0.010 0.050 BSC 0.150 0.157 0.228 0.244 0.016 0.050 MAX MIN 1.35 1.75 0.10 0.25 0.35 0.49 0.25 0.19 1.27 BSC 3.80 4.00 5.80 6.20 0.40 SOICN .EPS DIM A A1 B C e E H L 1.27 VARIATIONS: 1 INCHES TOP VIEW DIM D D D MIN 0.189 0.337 0.386 MAX 0.197 0.344 0.394 MILLIMETERS MIN 4.80 8.55 9.80 MAX 5.00 8.75 10.00 N MS012 8 AA 14 AB 16 AC D A B e C 0-8 A1 L FRONT VIEW SIDE VIEW PROPRIETARY INFORMATION TITLE: PACKAGE OUTLINE, .150" SOIC APPROVAL DOCUMENT CONTROL NO. 21-0041 REV. B 1 1 Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 15 (c) 2006 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc. MAX5940A/MAX5940B/MAX5940C/MAX5940D Package Information (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information, go to www.maxim-ic.com/packages.) Mouser Electronics Authorized Distributor Click to View Pricing, Inventory, Delivery & Lifecycle Information: Maxim Integrated: MAX5940AESA+ MAX5940AESA+T MAX5940BESA+ MAX5940BESA+T MAX5940CESA+ MAX5940CESA+T MAX5940DESA+ MAX5940DESA+T