19-5732; Rev 2; 8/11 IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET The MAX5981 provides a complete interface for a powered device (PD) to comply with the IEEE® 802.3af/at standard in a power-over-ethernet (PoE) system. The MAX5981 provides the PD with a detection signature, classification signature, and an integrated isolation power switch with inrush current control. During the inrush period, the MAX5981 limits the current to less than 180mA before switching to the higher current limit (720mA to 880mA) when the isolation power MOSFET is fully enhanced. The device features an input UVLO with wide hysteresis and long deglitch time to compensate for twisted-pair cable resistive drop and to assure glitch-free transition during power-on/-off conditions. The MAX5981 can withstand up to 100V at the input. The MAX5981 supports a 2-Event classification method as specified in the IEEE 802.3at standard and provides a signal to indicate when probed by a Type 2 power sourcing equipment (PSE). The device detects the presence of a wall adapter power source connection and allows a smooth switch over from the PoE power source to the wall power adapter. The MAX5981 also provides a power-good (PG) signal, two-step current limit and foldback, overtemperature protection, and di/dt limit. A sleep mode feature in the MAX5981 provides low power consumption while supporting Maintain Power Signature (MPS). An ultralow-power sleep mode feature in the MAX5981 further reduces power consumption while still supporting MPS. The MAX5981 also features an LED driver that is automatically activated during sleep mode. During sleep mode, the LED driver sources a periodic current (ILED) at 250Hz (MAX5981A) or 15.625kHz (MAX5981B). The MAX5981 is available in a 16-pin, 5mm x 5mm TQFN power package. The device is rated over the -40°C to +85°C extended temperature range. Features S Sleep Mode and Ultra-Low Power S IEEE 802.3af/at Compliant S 2-Event Classification or an External Wall Adapter Indicator Output S Simplified Wall Adapter Interface S PoE Classification 0–5 S 100V Input Absolute Maximum Rating S Inrush Current Limit of 180mA Maximum S Current Limit During Normal Operation Between 720mA and 880mA S Current Limit and Foldback S Legacy UVLO at 36V S LED Driver with Programmable LED Current S Overtemperature Protection S Thermally Enhanced, 5mm x 5mm, 16-Pin TQFN Applications IEEE 802.3af/at Powered Devices IP Phones, Wireless Access Nodes, IP Security Cameras WiMAXK Base Stations Ordering Information TEMP RANGE PINPACKAGE SLEEP MODE MAX5981AETE+ -40NC to +85NC 16 TQFN-EP* Yes MAX5981BETE+ -40NC to +85NC 16 TQFN-EP* Yes PART +Denotes a lead(Pb)-free/RoHS-compliant package. *EP = Exposed pad. WiMAX is a trademark of WiMAX Forum. IEEE is a registered service mark of the Institute of Electrical and Electronics Engineers, Inc. ________________________________________________________________ Maxim Integrated Products 1 For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. MAX5981A/MAX5981B General Description MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET ABSOLUTE MAXIMUM RATINGS VDD to VSS...........................................................-0.3V to +100V DET, RTN, WAD, PG, 2EC to VSS........................ -0.3V to +100V CLS, SL, WK, ULP, LED to VSS. ..............................-0.3V to +6V Maximum Current on CLS (100ms maximum)..................100mA Continuous Power Dissipation (TA = +70NC) (Note 1) TQFN (derate 28.6mW/NC above +70NC) Multilayer Board......................................................2285.7mW Package Thermal Resistance (Note 2) BJA. ..............................................................................35NC/W BJC..............................................................................2.7NC/W Operating Temperature Range........................... -40NC to +85NC Maximum Junction Temperature......................................+150NC Storage Temperature Range............................. -65NC to +150NC Lead Temperature (soldering, 10s)............................... +300NC Soldering Temperature.................................................. +260NC Note 1: Maximum power dissipation is obtained using JEDEC JESD51-5 and JESD51-7 specifications. Note 2: Package thermal resistances were obtained using the method described in JEDEC specification JESD51-7, using a fourlayer board. For detailed information on package thermal considerations, refer to www.maxim-ic.com/thermal-tutorial. 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 = (VDD - VSS) = 48V, RDET = 24.9kω, RCLS = 615ω, and RSL = 60.4kω. RTN, WAD, PG, 2EC, WK, and ULP unconnected, all voltages are referenced to VSS, unless otherwise noted. TA = TJ = -40NC to +85NC, unless otherwise noted. Typical values are at TA = +25NC.) (Note 3) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS 10 FA kI DETECTION MODE Input Offset Current Effective Differential Input Resistance IOFFSET dR VIN = 1.4V to 10.1V (Note 4) VIN = 1.4V up to 10.1V with 1V step, VDD = RTN = WAD = PG = 2EC (Note 5) 23.95 25.00 25.50 22.0 22.8 23.6 CLASSIFICATION MODE Classification Disable Threshold VTH,CLS VIN rising (Note 6) Classification Stability Time Classification Current 0.2 ICLASS VIN = 12.5V to 20.5V, VDD = RTN = WAD = PG = 2EC V ms Class 0, RCLS = 619I 0 3.96 Class 1, RCLS = 117I 9.12 11.88 Class 2, RCLS = 66.5I 17.2 19.8 Class 3, RCLS = 43.7I 26.3 29.7 Class 4, RCLS = 30.9I 36.4 43.6 Class 5, RCLS = 21.3I 52.7 63.3 mA TYPE 2 (802.3at) CLASSIFICATION MODE Mark Event Threshold VTHM VIN falling 10.1 Hysteresis on Mark Event Threshold 10.7 11.6 0.84 Mark Event Current IMARK VIN falling to enter mark event, 5.2V P VIN P 10.1V 0.25 Reset Event Threshold VTHR VIN falling 2.8 V V 0.85 mA 4 5.2 V 60 V 0.27 0.55 mA POWER MODE VIN Supply Voltage Range VIN Supply Current IQ 2 _______________________________________________________________________________________ IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET (VIN = (VDD - VSS) = 48V, RDET = 24.9kω, RCLS = 615ω, and RSL = 60.4kω. RTN, WAD, PG, 2EC, WK, and ULP unconnected, all voltages are referenced to VSS, unless otherwise noted. TA = TJ = -40NC to +85NC, unless otherwise noted. Typical values are at TA = +25NC.) (Note 3) MIN TYP MAX UNITS VIN Turn-On Voltage PARAMETER VON VIN rising 34.3 35.4 36.6 V VIN Turn-Off Voltage VOFF VIN falling 30 V (Note 7) 4.2 V VIN falling from 40V to 20V (Note 8) 30 tDELAY = minimum PG current pulse width after entering into power mode 87 VIN Turn-On/-Off Hysteresis VIN Deglitch Time SYMBOL VHYST_ UVLO tOFF_DLY Inrush to Operating Mode Delay tDELAY Isolation Power MOSFET On-Resistance RON_ISO RTN Leakage Current IRTN_LKG CONDITIONS IRTN = 600mA 120 Fs 96 105 TJ = +25NC 0.5 0.7 TJ = +85NC 0.65 1 I TJ = +125NC 0.8 10 FA VRTN = 12.5V to 30V ms CURRENT LIMIT Inrush Current Limit Current Limit During Normal Operation IINRUSH ILIM Foldback Threshold During initial turn-on period, VRTN = 1.5V 90 135 180 mA After inrush completed, VRTN = 1V 720 800 880 mA VRTN (Note 9) 13 16.5 V VWAD rising, VIN = 14V to 48V (referenced to RTN) 8 10 V LOGIC WAD Detection Threshold VWAD-REF WAD Detection Threshold Hysteresis WAD Input Current VWAD falling, VRTN = 0V, VSS unconnected IWAD-LKG 9 0.725 VWAD = 10V (referenced to RTN) 2EC Sink Current V2EC = 3.5V (referenced to RTN), VSS disconnected 2EC Off-Leakage Current V2EC = 48V PG Sink Current VRTN = 1.5V, VPG = 0.8V, during inrush period PG Off-Leakage Current VPG = 60V 1 125 1.5 230 V 3.5 FA 2.25 mA 1 FA 375 FA 1 FA 3 V SLEEP MODE VTH SL Logic Threshold VWK falling and VULP rising and falling Falling SL Current RSL = 0I WK and ULP Logic Threshold LED Current Amplitude ILED 1.5 0.75 0.8 0.85 140 RSL = 60.4kI, VLED = 3.5V 10 10.5 11.5 RSL = 30.2kI, VLED = 3.75V 19.5 20.9 22.5 RSL = 30.2kI, VLED = 4V V FA mA 19 _______________________________________________________________________________________ 3 MAX5981A/MAX5981B ELECTRICAL CHARACTERISTICS (continued) MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET ELECTRICAL CHARACTERISTICS (continued) (VIN = (VDD - VSS) = 48V, RDET = 24.9kω, RCLS = 615ω, and RSL = 60.4kω. RTN, WAD, PG, 2EC, WK, and ULP unconnected, all voltages are referenced to VSS, unless otherwise noted. TA = TJ = -40NC to +85NC, unless otherwise noted. Typical values are at TA = +25NC.) (Note 3) PARAMETER SYMBOL CONDITIONS MIN LED Current Programmable Range 10 20.5 LED Current with Grounded SL VSL = 0V LED Current Frequency fILED Normal and ULP sleep mode LED Current Duty Cycle DILED Normal and ULP sleep mode VDD Current Amplitude IVDD Normal sleep mode, VLED = 3.5V Internal Current Duty Cycle TYP DIVDD 24.5 MAX UNITS 20 mA 28.5 mA MAX5981A 250 Hz MAX5981B 15.625 kHz 25 10 11 % 12 mA 75 Normal and ULP sleep modes % Internal Current Enable Time tMPS ULP sleep mode 76 84 92 ms Internal Current Disable Time tMPDO ULP sleep mode 205 228 250 ms THERMAL SHUTDOWN Thermal-Shutdown Threshold TSD Thermal-Shutdown Hysteresis TJ rising +140 NC TJ falling 28 NC All devices are 100% production tested at TA = +25NC. Limits over temperature are guaranteed by design. The input offset current is illustrated in Figure 1. Effective differential input resistance is defined as the differential resistance between VDD and VSS. See Figure 1. Classification current is turned off whenever the device is in power mode. UVLO hysteresis is guaranteed by design, not production tested. A 20V glitch on input voltage, which takes VDD below VON shorter than or equal to tOFF_DLY does not cause the MAX5981A/MAX5981B to exit power-on mode. Note 9: In power mode, current-limit foldback is used to reduce the power dissipation in the isolation MOSFET during an overload condition across VDD and RTN. Note Note Note Note Note Note 3: 4: 5: 6: 7: 8: 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 Figure 1. Effective Differential Input Resistance/Offset Current 4 _______________________________________________________________________________________ IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET SIGNATURE RESISTANCE vs. INPUT VOLTAGE 25.5 RSIGNATURE (kI) IIN (mA) 0.3 0.2 TA = -40NC 25.0 TA = +25NC 24.5 0.1 TA = +85NC 4 2 0 2 4 6 8 TA = +25NC -2 -4 2 0 10 TA = +85NC 0 24.0 0 TA = -40NC MAX5981 toc03 IIN = IVDD + IDET RDET = 24.9kI RTN = 2EC = PG = WAD = VDD INPUT OFFSET CURRENT (FA) IIN = IVDD + IDET RDET = 25.4kI RTN = 2EC = PG = WAD = VDD -40°C P TA P +85NC 0.4 26.0 MAX5981 toc01 0.5 INPUT OFFSET CURRENT vs. INPUT VOLTAGE MAX5981 toc02 DETECTION CURRENT vs. INPUT VOLTAGE 4 6 8 10 0 2 4 VIN (V) VIN (V) 6 8 10 VIN (V) CLASSIFICATION CURRENT vs. INPUT VOLTAGE CLASSIFICATION SETTLING TIME MAX5981 toc05 MAX5981 toc04 70 CLASS 5 60 VIN 10V/div IIN (mA) 50 CLASS 4 40 30 CLASS 3 20 CLASS 2 IIN 200mA/div VCLS 1V/div CLASS 1 10 CLASS 0 RCLS = 30.9I 0 5 0 10 15 20 25 30 100Fs/div VIN (V) 2EC SINK CURRENT vs. 2EC VOLTAGE TA = +85NC 1.2 0.8 TA = +85NC 200 150 VSS FLOATING V2EC REFERENCED TO RTN VWAD = 14V 0.4 100 0 0 10 20 30 V2EC (V) 40 50 60 150 MAX5981 toc08 TA = -40NC TA = +25NC 250 IPG (FA) I2EC (mA) 1.6 300 INRUSH CURRENT LIMIT (mA) TA = +25NC MAX5981 toc07 TA = -40NC MAX5981 toc06 2.0 INRUSH CURRENT LIMIT vs. RTN VOLTAGE PG SINK CURRENT vs. PG VOLTAGE 130 110 90 70 50 50 0 10 20 30 VPG (V) 40 50 60 0 10 20 30 40 50 60 VRTN (V) _______________________________________________________________________________________ 5 MAX5981A/MAX5981B Typical Operating Characteristics (VIN = (VDD - VSS) = 54V, RDET = 24.9kω, RCLS = 615ω, and RSL = 60.4kω. RTN, WAD, PG, 2EC, WK, and ULP unconnected; all voltages are referenced to VSS.) Typical Operating Characteristics (continued) (VIN = (VDD - VSS) = 54V, RDET = 24.9kω, RCLS = 615ω, and RSL = 60.4kω. RTN, WAD, PG, 2EC, WK, and ULP unconnected; all voltages are referenced to VSS.) INRUSH CONTROL WAVEFORM WITH TYPE 2 CLASSIFICATION NORMAL OPERATION CURRENT LIMIT vs. RTN VOLTAGE MAX5981 toc10 MAX5981 toc09 900 800 CURRENT LIMIT (mA) VPG 0V 10V/div 700 V2EC 0V 40V/div 600 500 V 0V RTN 50V/div USING TYPICAL APPLICATION CIRCUIT 2EC PULLED UP TO VDD WITH 10kI 400 0A IRTN 100mA/div 300 200 VDD 0V 50V/div 100 0 10 20 30 40 50 20ms/div 60 VRTN (V) INRUSH CONTROL WAVEFORM WITH TYPE 2 CLASSIFICATION -40NC < TA < +85NC VPG 0V 10V/div 22 V2EC 0V 40V/div VRTN 0V 50V/div ILED (mA) USING TYPICAL APPLICATION CIRCUIT 2EC PULLED UP TO VDD WITH 10kI 25 IRTN 0A 200mA/div MAX5981 toc12 LED CURRENT vs. RSL MAX5981 toc11 19 16 13 VDD 0V 50V/div 10 0 5 10 15 20 25 30 35 40 45 50 55 60 65 20ms/div RSL (kI) LED CURRENT vs. LED VOLTAGE MAX5981 toc13 25 RSL = 30.2kI 20 ILED (mA) MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET 15 RSL = 60.4kI 10 5 0 1 2 3 4 5 VLED (V) 6 _______________________________________________________________________________________ IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET 2 DET 3 I.C. 4 ULP WK SL LED 13 + MAX5981A MAX5981B EP* 5 6 7 8 RTN VDD 14 RTN 1 15 VSS N.C. 16 VSS TOP VIEW 12 CLS 11 2EC 10 PG 9 WAD TQFN CONNECT TO VSS. Pin Description PIN NAME 1 N.C. No Connection. Not internally connected. FUNCTION 2 VDD 3 DET Positive Supply Input. Connect a 68nF (min) bypass capacitor between VDD and VSS. Detection Resistor Input. Connect a signature resistor (RDET = 24.9kI) from DET to VDD. 4 I.C. Internally Connected. Leave unconnected. 5, 6 VSS Negative Supply Input. VSS connects to the source of the integrated isolation n-channel power MOSFET. 7, 8 RTN Drain of Isolation MOSFET. RTN connects to the drain of the integrated isolation n-channel power MOSFET. Connect RTN to the downstream DC-DC converter ground as shown in the Typical Application Circuit. WAD Wall Power Adapter Detector Input. Wall adapter detection is enabled the moment VDD - VSS crosses the mark event threshold. Detection occurs when the voltage from WAD to RTN is greater than 9V. When a wall power adapter is present, the isolation n-channel power MOSFET turns off, 2EC current sink turns on. Connect WAD directly to RTN when the wall power adapter or other auxiliary power source is not used. PG Open-Drain Power-Good Indicator Output. PG sinks 230FA to disable the downstream DC-DC converter while turning on the hot-swap MOSFET switch. PG current sink is disabled during detection, classification, and in the steady-state power mode. The PG current sink is turned on to disable the downstream DC-DC converter when the device is in sleep mode. 9 10 _______________________________________________________________________________________ 7 MAX5981A/MAX5981B Pin Configuration MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET Pin Description (continued) PIN NAME FUNCTION 11 2EC 2-Event Classification Detect or Wall Adapter Detect Output. A 1.5mA current sink is enabled at 2EC when a Type 2 PSE or a wall adapter is detected. When powered by a Type 2 PSE, the 2EC current sink is enabled after the isolation MOSFET is fully on until VIN drops below the UVLO threshold. 2EC is latched when powered by a Type 2 PSE until VIN drops below the reset threshold. 2EC also asserts when a wall adapter supply, typically greater than 9V, is applied between WAD and RTN. 2EC is not latched if asserted by WAD. The 2EC current sink is turned off when the device is in sleep mode. 12 CLS Classification Resistor Input. Connect a resistor (RCLS) from CLS to VSS to set the desired classification current. See the classification current specifications in the Electrical Characteristics table to find the resistor value for a particular PD classification. 13 LED LED Driver Output. During sleep mode, LED sources a periodic current (ILED). The amplitude of ILED is set by RSL according to the formula ILED (in A) = 645.75/(RSL + 1200). 14 SL Sleep Mode Enable Input. A falling edge on SL brings the device into sleep mode (VSL must drop below 0.75V). An external resistor (RSL) connected between SL and VSS sets the LED current (ILED). 15 WK Wake Mode Enable Input. WK has an internal 2.5kI pullup resistor to the internal 5V bias rail. A falling edge on WK brings the device out of sleep mode and into the normal operating mode (wake mode). 16 ULP Ultra-Low-Power Enable Input (in Sleep Mode). ULP has an internal 50kI pullup resistor to the internal 5V bias rail. A falling edge on SL while ULP is asserted low enables ultra-low-power mode. When ultralow-power mode is enabled, the power consumption of the device is reduced even lower than normal sleep while still supporting MPS. –– EP Exposed Pad. Do not use EP as an electrical connection to VSS. EP is internally connected to VSS through a resistive path and must be connected to VSS externally. To optimize power dissipation, solder the exposed pad to a large copper power plane. 8 _______________________________________________________________________________________ IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET VDD VDD EN CLS CLASSIFICATION VDD 2EC D SET Q CLR Q D SET Q CLR Q 5V REGULATOR VDD 1.5mA 5V PG 46µA DET VON/VOFF VDD 230µA VDD THERMAL SHUTDOWN WAD R S Q 9V tDELAY ISWITCH VSS RTN ISOLATION SWITCH K x ISWITCH S I0 1/K I1 MUX MAX5981A MAX5981B SL 5V 2.5kI WK LOGIC LED 5V 50kI ULP _______________________________________________________________________________________ 9 MAX5981A/MAX5981B Simplified Block Diagram MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET Typical Operating Circuit 2-EVENT CLASSIFICATION DETECTION GND 2EC VDD RJ-45 AND BRIDGE RECTIFIER ENABLE 2EC/WAD DET MAX5981A MAX5981B 1.5mA DC-DC CONVERTER WAD CLS SMAJ58A 24V/48V BATTERY RCLS -54V GND PG RDET 24.9kI 68nF IN+ IN- VSS RTN WK SL 1kI ISOLATED SLEEP MODE INPUT ULP -54V LED ISOLATED ULP MODE INPUT -54V -54V 10 ������������������������������������������������������������������������������������� IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET Operating Modes Depending on the input voltage (VIN = VDD - VSS), the MAX5981 operates in four different modes: PD detection, PD classification, mark event, and PD power. The devices enter PD detection mode when the input voltage is between 1.4V and 10.1V. The device enters PD classification mode when the input voltage is between 12.6V and 20V. The device enters PD power mode once the input voltage exceeds VON. Detection Mode (1.4V P VIN P 10.1V) In detection mode, the power source equipment (PSE) applies two voltages on VIN in the 1.4V to 10.1V range (1V step minimum) and then records the current measurements at the two points. The PSE then computes DV/DI to ensure the presence of the 24.9kI signature resistor. Connect the signature resistor (RDET) from VDD to DET for proper signature detection. The MAX5981 pulls DET low in detection mode. DET goes high impedance when the input voltage exceeds 12.5V. In detection mode, most of the MAX5981 internal circuitry is off and the offset current is less than 10µA. If the voltage applied to the PD is reversed, install pro tection diodes at the input terminal to prevent internal damage to the MAX5981 (see the Typical Application Circuit). Since the PSE uses a slope technique (DV/DI) to calculate the signature resistance, the DC offset due to the protection diodes is subtracted and does not affect the detection process. Classification Mode (12.6V P VIN P 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. Class 0–5 is defined as shown in Table 1. (The IEEE 802.3af/at standard defines only Class 0–4 and Class 5 for any special requirement.) An external resistor (RCLS) connected from CLS to VSS sets the classification current. The PSE determines the class of a PD by applying a volt age at the PD input and measuring the current sourced out of the PSE. When the PSE applies a voltage between 12.6V and 20V, the MAX5981A/MAX5981B exhibit a current characteristic with a value shown in Table 1. The PSE uses the classification current information to classify the power requirement of the PD. The classification current includes the current drawn by RCLS and the supply current of the MAX5981A/MAX5981B so the total current drawn by the PD is within the IEEE 802.3af/at standard figures. The classification current is turned off whenever the device is in power mode. 2-Event Classification and Detection During 2-Event classification, a Type 2 PSE probes PD for classification twice. In the first classification event, the PSE presents an input voltage between 12.6V and 20.5V and the MAX5981A/MAX5981B present the programmed load ICLASS. The PSE then drops the probing voltage below the mark event threshold of 10.1V and the MAX5981A/MAX5981B present the mark current (IMARK). This sequence is repeated one more time. When the MAX5981A/MAX5981B are powered by a Type 2 PSE, the 2-Event identification output 2EC asserts low after the internal isolation n-channel MOSFET is fully turned on. 2EC current sink is turned off when VDD goes below the UVLO threshold (VOFF) and turns on when VDD goes above the UVLO threshold (VON), unless VDD goes below VTHR to reset the latched output of the Table 1. Setting Classification Current IEEE 802.3at PD CLASSIFICATION CURRENT SPECIFICATION (mA) CLASS MAXIMUM POWER USED BY PD (W) RCLS (I) VIN* (V) MIN MAX MIN 0 0.44 to 12.95 615 12.6 to 20 0 4 0 5 1 0.44 to 3.84 117 12.6 to 20 9 12 8 13 2 3.84 to 6.49 66.5 12.6 to 20 17 20 16 21 CLASS CURRENT SEEN AT VIN (mA) MAX 3 6.49 to 12.95 43.7 12.6 to 20 26 30 25 31 4 12.95 to 25.5 30.9 12.6 to 20 36 44 35 45 5 > 25.5 21.3 12.6 to 20 54 64 51 68 *VIN is measured across the MAX5981A/MAX5981B input VDD to VSS. ______________________________________________________________________________________ 11 MAX5981A/MAX5981B Detailed Description MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET Type 2 PSE detection flag. Alternatively, the 2EC output also serves as a wall adapter detection output when the MAX5981A/MAX5981B are powered by an external wall power adapter. See the Wall Power Adapter Detection and Operation section for more information. Power Mode (Wake Mode) The MAX5981A/MAX5981B enter power mode when VIN rises above the undervoltage lockout threshold (VON). When VIN rises above VON, the MAX5981A/MAX5981B turn on the internal n-channel isolation MOSFET to connect VSS to RTN with inrush current limit internally set to 135mA (typ). The isolation MOSFET is fully turned on when the voltage at RTN is near VSS and the inrush current is reduced below the inrush limit. Once the isolation MOSFET is fully turned on, the MAX5981A/MAX5981B change the current limit to 800mA. The open-drain power-good output (PG) remains low for a minimum of tDELAY until the power MOSFET fully turns on to keep the downstream DC-DC converter disabled during inrush. Undervoltage Lockout The MAX5981A/MAX5981B operate up to a 60V supply voltage with a turn-on UVLO threshold (VON) at 35.4V and a turn-off UVLO threshold (VOFF) at 31V. When the input voltage is above VON, the MAX5981A/MAX5981B enter power mode and the internal MOSFET is turned on. When the input voltage goes below VOFF for more than tOFF_DLY, the MOSFET turns off. Sleep and Ultra-Low-Power Sleep Modes The MAX5981A/MAX5981B feature a sleep mode, which pulls PG low while keeping the internal n-channel isola tion MOSFET turned on. The PG output is used to dis able downstream DC-DC converters reducing the power consumption of the overall PD system in sleep mode. In sleep mode, the LED driver output (LED) sources peri odic current pulses. The LED current ILED is set by an external resistor RSL, see the Applications Information section for more information. An ultra-low-power sleep mode allows the MAX5981A/ MAX5981B to further reduce power consumption while maintaining the power signature of the standard. The ultra-low-power enable input ULP is internally held high with a 50kI pullup resistor to the internal 5V bias of the MAX5981A/MAX5981B. Set ULP to logic-low and apply a falling edge to SL to enable ultra-low-power sleep mode. Apply a falling edge on the wake-mode enable input (WK) to disable sleep or ultra-low-power sleep mode and resume normal operation. LED Driver The MAX5981A/MAX5981B drive an LED connected from the output LED to VSS. During sleep mode/ultra-lowpower sleep mode, the LED is driven by current pulses with the amplitude set by the resistor connected from SL to VSS. The LED driver current amplitude is programmable from 10mA to 20mA using RSL according to the following formula: ILED = 645.75 (in amperes) RSL + 1200 Power-Good Output An open-drain output (PG) is used to allow disabling downstream DC-DC converter until the n-channel isola tion MOSFET is fully turned on. PG is pulled low to VSS for a period of tDELAY and until the internal isolation MOSFET is fully turned on. The PG is also pulled low during sleep mode and coming out of thermal shutdown. Thermal-Shutdown Protection The MAX5981A/MAX5981B include thermal protection from excessive heating. If the junction temperature exceeds the thermal-shutdown threshold of +140NC, the MAX5981A/MAX5981B turn off the internal power MOSFET, LED driver, and 2EC current sink. When the junction temperature falls below +112NC, the device enters inrush mode and then return to power mode. Inrush mode ensures the downstream DC-DC converter is turned off as the internal power MOSFET is turned on. Wall Power Adapter Detection and Operation For applications where an auxiliary power source such as a wall power adapter is used to power the PD, the MAX5981A/MAX5981B feature wall power adapter detection. The MAX5981A/MAX5981B give highest priority to the WAD and smoothly switch the power supply to WAD when it is detected. Once the input voltage (VDD VSS) exceeds the mark event threshold, the MAX5981A/ MAX5981B enable wall adapter detection. The wall power adapter is connected from WAD to RTN. The MAX5981A/MAX5981B detect the wall power adapter when the voltage from WAD to RTN is greater than 9V. When a wall power adapter is detected, the internal n-channel isolation MOSFET turns off, 2EC current sink turns on, and classification current is disabled if VIN is in the classification range. 12 ������������������������������������������������������������������������������������� IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET 3) Use short and wide traces for high-power paths. 4) Use the MAX5981A/MAX5981B evaluation kit layout as a reference. Operation with 12V Adapter Layout Procedure Careful PCB layout is critical to achieve high efficiency and low EMI. Follow these layout guidelines for optimum performance: 5) Place enough vias in the pad for the EP of the MAX5981A/MAX5981B so that heat generated inside can be effectively dissipated by the PCB copper. The recommended spacing for the vias is 1mm to 1.2mm pitch. The thermal vias should be plated (1oz copper) and have a small barrel diameter (0.3mm to 0.33mm). 1) Place the input capacitor, classification resistor, and transient voltage suppressor as close as possible to the MAX5981A/MAX5981B. 2) Use large SMT component pads for power dissipating devices such as the MAX5981A/MAX5981B and the external diodes. 2-EVENT CLASSIFICATION (ASSERTED ON) GND VDD RJ-45 AND BRIDGE RECTIFIER DET MAX5981A MAX5981B 1.5mA DC-DC CONVERTER WAD 12V BATTERY RCLS -54V GND ENABLE 2EC/WAD CLS SMAJ58A IN+ PG RDET 24.9kI 68nF 2EC VSS IN- RTN THIS CIRCUIT ACHIEVES PROPER 2EC LOGIC WHEN BATTERY IS < 12.5V Figure 2. Typical Configuration When Using a 12V Wall Power Adapter ______________________________________________________________________________________ 13 MAX5981A/MAX5981B Applications Information MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET Typical Application Circuit ISOLATED 2-EVENT CLASSIFICATION OUTPUT GND GND 2EC VDD 2EC/WAD VAC DET 68nF MAX5981A MAX5981B CLS SMAJ58A VAC WAD 1.4mA 24/48V BATTERY 43.7I -54V WALK MODE INPUT PG PG 24.9kI VSS RTN WK SL RTN 1kI ISOLATED SLEEP MODE INPUT 60.4kI ULP -54V LED ISOLATED ULP MODE INPUT -54V -54V GND 33kI 1.37MI 249I 4.7µF 0.1µF 51.5kI ISOLATED +5.3V/2A GND RTN PG ULVO/EN IN UFLG 0.1µF 0.1µF 22µF VCC VCC ISOLATED RTN FB 10kI CS COMP MAX15000 22.1I NDRV GND CS CS RT 649I 619I 1kI 330pF 18.1kI 8.2nF 0.75I 8.06kI 0.1µF 4.99kI VCC 4.99kI 1kI RTN 100pF 33nF 8.06kI 1kI 2.49kI 2.2nF RTN ISOLATED RTN 14 ������������������������������������������������������������������������������������� IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET PROCESS: BiCMOS For the latest package outline information and land patterns, (footprints) go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE OUTLINE NO. LAND PATTERN NO. 16 TQFN-EP T1655+4 21-0140 90-0121 ______________________________________________________________________________________ 15 MAX5981A/MAX5981B Package Information Chip Information MAX5981A/MAX5981B IEEE 802.3af/at-Compliant, Powered Device Interface Controllers with Integrated Power MOSFET Revision History REVISION NUMBER REVISION DATE 0 1/11 1 8/11 2 8/11 DESCRIPTION Initial release Revised General Description, Absolute Maximum Ratings, Electrical Characteristics, Pin Description, Typical Operating Circuit, LED Driver section, and Typical Application Circuit. Revised General Description, Electrical Characteristics, Typical Operating Characteristics, and Pin Description. PAGES CHANGED — 1–8, 10, 11, 12, 14 1, 4, 6, 8 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. 16 © 2011 Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc.