LM5066 LM5066 High Voltage System Power Management and Protection IC with PMBus Literature Number: SNVS655F LM5066 High Voltage System Power Management and Protection IC with PMBus General Description Features The LM5066 combines a high performance hot swap controller with a PMBus™ compliant SMBus/I 2C interface to accurately measure, protect and control the electrical operating conditions of systems connected to a backplane power bus. The LM5066 continuously supplies real-time power, voltage, current, temperature and fault data to the system management host via the SMBus interface. The LM5066 control block includes a unique hot swap architecture that provides current and power limiting to protect sensitive circuitry during insertion of boards into a live system backplane, or any other "hot" power source. A fast acting circuit breaker prevents damage in the event of a short circuit on the output. The input under-voltage and over-voltage levels and hysteresis are configurable, as well as the insertion delay time and fault detection time. A temperature monitoring block on the LM5066 interfaces with a low-cost external diode for monitoring the temperature of the external MOSFET or other thermally sensitive components. The PGD output provides a fast indicator when the input and/or output voltages are outside their programmed ranges. LM5066 current measurement accuracy is ±4.5% over the operating temperature range. The LM5066 monitoring block computes both the real-time and average values of subsystem operating parameters (VIN, IIN, PIN, VOUT) as well as the peak power. Accurate power averaging is accomplished by averaging the product of the input voltage and current. A black box (Telemetry/Fault Snapshot) function captures and stores telemetry data and device status in the event of a warning or a fault. ■ Input voltage range: 10V to 80V ■ Programmable 26 mV or 50 mV Current Limit Threshold with Power Limiting (MOSFET Power Dissipation Limiting) ■ Real time monitoring of VIN, VOUT, IIN, PIN, VAUX with 12-bit resolution and 1 kHz sampling rate ■ Configurable Circuit Breaker protection for hard shorts ■ Configurable Under-Voltage and Over-Voltage protection ■ Remote temperature sensing with programmable warning ■ ■ ■ ■ ■ ■ ■ ■ ■ and shutdown thresholds Detection and notification of damaged MOSFET condition Power measurement accuracy: ±4.5% over temperature True Input Power averages dynamic power readings Averaging of VIN, IIN, PIN, and VOUT over programmable interval ranging from 0.001 to 4 seconds Programmable WARN and FAULT thresholds with SMBA notification Black box capture of telemetry measurements and device status triggered by WARN or FAULT condition I2C/SMBus interface and PMBus compliant command structure Full featured application development software eTSSOP-28 package Applications ■ Server Backplane Systems ■ Base Station Power Distribution Systems ■ Solid State Circuit Breaker Typical Application Schematic 30115911 © 2011 National Semiconductor Corporation 301159 www.national.com LM5066 High Voltage System Power Management and Protection IC with PMBus™ August 22, 2011 LM5066 Connection Diagram Solder exposed pad to ground. 30115902 Ordering Information Order Number Package Type Package Drawing Supplied As LM5066PMH NOPB eTSSOP-28 MXA28A 48 units in rail LM5066PMHE NOPB eTSSOP-28 MXA28A 250 units in tape and reel LM5066PMHX NOPB eTSSOP-28 MXA28A 2,500 units in tape and reel Pin Descriptions Pin No. Name Pad Exposed Pad Description Exposed pad of TSSOP package Applications Information Solder to the ground plane to reduce thermal resistance 1 OUT Output feedback Connect to the output rail (external MOSFET source). Internally used to determine the MOSFET VDS voltage for power limiting, and to monitor the output voltage. 2 GATE Gate drive output Connect to the external MOSFET's gate. 3 SENSE Current sense input 4 VIN_K 5 VIN Positive supply kelvin pin The input voltage is measured on this pin. Positive supply input 6 N/C No connection 7 UVLO/EN Under-voltage lockout www.national.com The voltage across the current sense resistor (RS) is measured from VIN_K to this pin. If the voltage across RS reaches over-current threshold the load current is limited and the fault timer activates. This pin is the input supply connection for the device. An external resistor divider from the system input voltage sets the under-voltage turn-on threshold. An internal 20 µA current source provides hysteresis. The enable threshold at the pin is nominally 2.48V. This pin can also be used for remote shutdown control. 2 Name Description 8 OVLO Over-voltage lockout Applications Information An external resistor divider from the system input voltage sets the over-voltage turn-off threshold. An internal 21 µA current source provides hysteresis. The disable threshold at the pin is 2.46V. 9 AGND Circuit ground 10 GND Circuit ground Analog device ground. Connect to GND at the pin. 11 SDAI SMBus data input pin Data input pin for SMBus. Connect to SDAO if the application does not require unidirectional isolation devices. 12 SDAO SMBus data output pin Data output pin for SMBus. Connect to SDAI if the application does not require unidirectional isolation devices. 13 SCL SMBus clock 14 SMBA SMBus alert line Clock pin for SMBus. 15 VREF Internal Reference Internally generated precision reference used for analog to digital conversion. Connect a 1 µF capacitor on this pin to ground for bypassing. 16 DIODE External diode Connect this to a diode-configured MMBT3904 NPN transistor for temperature monitoring. 17 VAUX Auxiliary voltage input Auxiliary pin allows voltage telemetry from an external source. Full scale input of 2.97V. 18 ADR2 SMBUS address line 2 Tri- state address line. Should be connected to GND, VDD, or left floating. 19 ADR1 SMBUS address line 1 Tri - state address line. Should be connected to GND, VDD, or left floating. 20 ADR0 SMBUS address line 0 Tri - state address line. Should be connected to GND, VDD, or left floating. 21 VDD Internal sub-regulator output Internally sub-regulated 4.85V bias supply. Connect a 1 µF capacitor on this pin to ground for bypassing. 22 CL Current limit range Connect this pin to GND or leave floating to set the nominal over-current threshold at 50mV. Connecting CL to VDD will set the over-current threshold to be 26mV. 23 FB Power Good feedback An external resistor divider from the output sets the output voltage at which the PGD pin switches. The threshold at the pin is nominally 2.46V. An internal 20 µA current source provides hysteresis. 24 RETRY Fault retry input This pin configures the power up fault retry behavior. When this pin is connected to GND or left floating, the device will continually try to engage power during a fault. If the pin is connected to VDD, the device will latch off during a fault. 25 TIMER Timing capacitor An external capacitor connected to this pin sets the insertion time delay, fault timeout period and restart timing. 26 PWR Power limit set An external resistor connected to this pin, in conjunction with the current sense resistor (RS), sets the maximum power dissipation allowed in the external series pass MOSFET. 27 N/C No Connection 28 PGD Power Good indicator Alert pin for SMBus, active low. An open drain output. This output is high when the voltage at the FB pin is above VFBTH (nominally 2.46V) and the input supply is within its under-voltage and over-voltage thresholds. Connect to the output rail (external MOSFET source) or any other voltage to be monitored. 3 www.national.com LM5066 Pin No. LM5066 ESD Rating (Note 2) Human Body Model Storage Temperature Junction Temperature Absolute Maximum Ratings (Note 1) If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/ Distributors for availability and specifications. VIN, VIN_K, GATE, UVLO/EN, OUT, SENSE, PGD to GND (Note 6) OVLO, FB, TIMER, PWR to GND SCL, SDAI, SDAO, CL, ADR0, ADR1, ADR2, VDD, VAUX, DIODE, RETRY to GND SENSE to VIN_K, VIN to VIN_K, AGND to GND 2kV -65°C to +150°C +150°C Operating Ratings -0.3V to 100V -0.3V to 7.0V VIN, SENSE, OUT voltage 10V to 80V Junction Temperature -40°C to +125°C -0.3V to 6.0V -0.3V to +0.3V Electrical Characteristics Limits in standard type are for TJ = 25°C only; limits in boldface type apply over the junction temperature (TJ) range of -40°C to +125°C unless otherwise stated. Minimum and Maximum limits are guaranteed through test, design, or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise stated the following conditions apply: VIN = 48V. See (Note 3) and (Note 7). Symbol Parameter Conditions Min Typ Max Units Input (VIN Pin) IIN-EN Input Current, enabled VUVLO = 3V and VOVLO = 2V 7.2 9.5 mA PORIT Power On Reset threshold at VIN to trigger insertion timer VIN Increasing 7.8 9.0 V POREN Power On Reset threshold at VIN to enable all functions VIN Increasing 8.6 9.9 V PORHYS POREN Hysteresis VIN Decreasing 120 mV VDD Regulator (VDD pin) VDD IVDD = 0 mA 4.60 IVDD = 10 mA VDDILIM VDD Current Limit VDDPOR VDD Voltage Reset threshold 4.90 5.15 V -42 mA 4.85 -25 VDD Rising -30 V 4.1 V UVLO/EN, OVLO Pins UVLOTH UVLO threshold VUVLO Falling 2.41 2.48 2.55 V UVLOHYS UVLO hysteresis current UVLO = 1V UVLODEL UVLO delay Delay to GATE high 13 20 9 26 µA Delay to GATE low 13 UVLOBIAS UVLO bias current UVLO = 3V 1 µA OVLOTH OVLO threshold VOVLO Rising 2.39 2.46 2.53 V OVLOHYS OVLO hysteresis current OVLO = 1V -26 -21 -13 µA OVLODEL OVLO delay Delay to GATE high 13 Delay to GATE low 10 OVLOBIAS OVLO bias current OVLO = 1V µs µs 1 µA 110 mV 1 µA Power Good (PGD pin) PGDVOL Output low voltage ISINK = 2 mA PGDIOH Off leakage current VPGD = 80V FBTH FB Threshold VUVLO = 3V and VOVLO = 2V FBHYS FB Hysteresis Current FBDEL FB Delay 60 FB Pin FBLEAK www.national.com Off Leakage Current 2.41 2.46 2.52 V -25 -20 -15 µA Delay to PGD high 7.6 µs Delay to PGD low 9.2 µs VFB = 2.3V 4 1 µA Parameter Conditions Min Typ Max Units 16.5 19.5 22.5 mV Power Limit (PWR Pin) PWRLIM IPWR RSAT(PWR) Power limit sense voltage (VINSENSE) SENSE-OUT = 48V, RPWR = 121 kΩ SENSE-OUT = 24V, RPWR = 75 kΩ 23 mV PWR pin current VPWR = 2.5V -20 µA PWR pin impedance when disabled UVLO = 2V 135 Ω Gate Control (GATE Pin) IGATE Source current Normal Operation -26 -20 -10 µA Fault Sink current UVLO = 2V 3.4 4.2 5.3 mA POR Circuit Breaker sink current VIN - SENSE = 150 mV or VIN < PORIT, VGATE = 5V 50 115 180 mA 15 16.5 18 V VGATEZ Reverse-bias voltage of GATE to OUT GATE - OUT zener diode VGATECP Peak charge pump voltage in normal GATE - OUT operation (VIN = VOUT) 13.6 V OUT Pin IOUT-EN OUT bias current, enabled OUT = VIN, Normal operation 78 µA IOUT-DIS OUT bias current, disabled (Note 4) Disabled, OUT = 0V, SENSE = VIN -50 µA Current limit threshold voltage (VIN VSENSE) CL = VDD 23 26 29 CL = GND 47 50 53 Response time VIN-SENSE stepped from 0 mV to 80 mV 45 µs SENSE input current Enabled, SENSE = OUT 25 µA Disabled, OUT = 0V 66 Enabled, OUT = 0V 220 Current Limit VCL tCL ISENSE mV Circuit Breaker RTCB Circuit Breaker to Current Limit Ratio: CB/CL ratio bit = 0, ILim = 50 mV (VIN -VSENSE)CB/VCL CB/CL ratio bit = 1, ILim = 50 mV 1.64 1.94 2.23 3.28 3.87 4.45 CB/CL ratio bit = 0, ILim = 26 mV 1.88 CB/CL ratio bit = 1, ILim = 26 mV VCB tCB Circuit Breaker Threshold Voltage: (VIN - VSENSE) Response time V/V 3.75 CB/CL ratio bit = 0, ILim = 50 mV 80 96 110 CB/CL ratio bit = 1, ILim = 50 mV 164 193 222 CB/CL ratio bit = 0, ILim = 26 mV 39 48 57 CB/CL ratio bit = 1, ILim = 26 mV 79 96 113 0.42 0.83 µs 3.74 3.9 4.07 V 0.98 1.1 1.24 V VIN - SENSE stepped from 0 mV to 150 mV, time to GATE low, no load mV Timer (TIMER pin) VTMRH Upper threshold VTMRL Lower threshold Restart cycles End of 8th cycle 0.3 Re-enable Threshold ITIMER Insertion time current TIMER pin = 2V V 0.3 -5.9 -4.8 V -3.3 µA Sink current, end of insertion time 1.0 1.5 2.0 mA Fault detection current -95 -75 -50 µA Fault sink current 1.7 2.5 3.2 µA DCFAULT Fault Restart Duty Cycle tFAULT_DELAY Fault to GATE low delay TIMER pin reaches the upper threshold 0.5 % 12 µs Internal Reference VREF Reference Voltage 2.93 5 2.97 3.02 V www.national.com LM5066 Symbol LM5066 Symbol Parameter Conditions Min Typ Max Units ADC and MUX Resolution 12 Bits Integral Non-Linearity ADC only ±4 LSB tACQUIRE Acquisition + Conversion Time Any Channel 100 µs tRR Acquisition Round Robin Time Cycle all channels 1 ms CL = GND 75.8 mV CL = VDD 38.2 mV CL = GND 18.5 µV CL = VDD 9.3 µV 2.97 V INL Telemetry Accuracy IINFSR IINLSB Current input full scale range Current input LSB VAUXFSR VAUX input full scale range VAUXLSB VAUX input LSB 725 µV VINFSR Input voltage full scale range 89.3 V VINLSB Input voltage LSB IINACC Input Current Accuracy VIN – SENSE = 50mV, CL = GND -3.0 +3.0 % VACC VAUX, VIN, VOUT VIN, VOUT = 48V VAUX = 2.8V -2.7 +2.7 % Input Power Accuracy VIN = 48V, VIN – SENSE = 50mV, CL = VDD -4.5 +4.5 % 10 °C PINACC 21.8 mV Remote Diode Temperature Sensor TACC Temperature Accuracy Using Local Diode TA = 25°C to 85°C 2 Remote Diode Resolution IDIODE External Diode Current Source 9 High Level 250 Low Level 9.4 Diode Current Ratio bits 325 µA µA 25.9 PMBus Pin Thresholds (SMBA, SDA, SCL) VIL Data, Clock Input Low Voltage VIH Data, Clock Input High Voltage VOL Data Output Low Voltage ISINK = 3 mA ILEAK Input Leakage Current SDAI,SMBA,SCL = 5V 0.9 V 2.1 5.5 V 0 0.4 V 1 µA Configuration Pin Thresholds (CL, RETRY) VIH ILEAK Threshold Voltage Input Leakage Current V 3 CL, RETRY = 5V 5 µA Thermal (Note 5) θJA Junction to Ambient 29 °C/W θJC Junction to Case 4 °C/W Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is intended to be functional, but do not guarantee specific performance limits. For guaranteed specifications and conditions see the Electrical Characteristics. Note 2: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin. 2 kV rating for all pins except GATE which is rated for 1 kV. Note 3: Current out of a pin is indicated as a negative value. Note 4: OUT bias current (disabled) due to leakage current through an internal 1 MΩ resistance from SENSE to VOUT. Note 5: Junction to ambient thermal resistance is highly application and board layout dependent. Specified thermal resistance values for the package specified is based on a 4-layer, 4"x3", 2/1/1/2 oz. Cu board with 15 vias with 8 mil. diameter under the DAP. Note 6: The GATE pin voltage is typically 13.6V above VIN when the LM5066 is enabled. Therefore, the Absolute Maximum Rating for VIN applies only when the LM5066 is disabled, or for a momentary surge to that voltage since the Absolute Maximum Rating for the GATE pin is also 100V. Note 7: All limits are guaranteed. All electrical characteristics having room temperature limits are tested during production at TA = 25°C. All hot and cold limits are guaranteed by correlating the electrical characteristics to process and temperature variations and applying statistical process control. www.national.com 6 LM5066 Typical Performance Characteristics Unless otherwise specified the following conditions apply: TJ = 25°C, VIN = 48V. All graphs show junction temperature. VIN Pin Current Sense Pin Current (Enabled) 7.5 SENSE PIN CURRENT (ENABLED) (μA) VIN INPUT CURRENT (mA) 8.0 VIN = 80V 7.0 6.5 VIN = 48V 6.0 5.5 VIN = 10V 5.0 30 29 28 27 26 25 24 23 22 -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 30115976 30115971 Out Pin Current (Disabled) 150 120 OUTPUT PIN CURRNET (DISABLED) (μA) OUTPUT PIN CURRENT (ENABLED) (μA) Out Pin Current (Enabled) VIN = 80V 90 60 VIN = 48V 30 VIN = 10V 0 -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 0 -20 -40 VIN = 80V VIN = 48V -60 -80 VIN = 10V -100 -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) 30115974 30115973 Gate Zener Reverse Bias Voltage (VGATE - VOUT) Gate Pin Source Current -18.0 GATE PIN SOURCE CURRENT (μA) 18.0 GATE PIN VOLTAGE (V) 17.8 17.6 17.4 17.2 17.0 16.8 VIN = 10V to 80V 16.6 16.4 16.2 16.0 -18.5 -19.0 -19.5 -20.0 -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) 30115977 30115972 7 www.national.com LM5066 UVLO Threshold 2.50 30 UVLO THRESHOLD (V) VSNS AT POWER THRESHOLD (mV) VSNS at Power Limit Threshold RPWR = 75 kΩ 25 VIN = 24V 20 VIN = 48V 15 10 2.48 VIN = 10V 2.46 2.44 VIN = 48V, 80V VIN = 80V 5 2.42 0 -40 -20 -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 30115981 30115989 UVLO Hysteresis Current FB Threshold 2.48 20.7 20.6 FB THRESHOLD (V) UVLO HYSTERESIS CURRENT (μA) 20.8 VIN = 10V to 80V 20.5 2.46 2.44 2.42 20.4 -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) 30115982 30115979 OVLO Threshold OVLO Hysteresis -18 OVLO HYSTERESIS CURRENT (μA) OVLO THRESHOLD (V) 2.48 VIN = 10V to 80V 2.46 2.46 2.44 -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) -22 VIN = 10V to 80V -24 -26 -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 30115983 www.national.com -20 30115984 8 Current Limit Threshold -23.0 CURRENT LIMIT THRESHOLD (mV) 55 -23.5 FB HYSTERESIS (μA) LM5066 FB Pin Hysteresis -24.0 -24.5 -25.0 -25.5 -26.0 -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) 50 45 CL = GND 40 35 30 CL = VDD 25 20 -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 30115980 30115986 Reference Voltage 2.965 200 180 CL = GND, CB/CL BIT = HIGH 2.960 160 140 120 VREF (V) CIRCUIT BREAKER THRESHOLD (mV) Circuit Breaker Threshold CL = GND, CB/CL BIT = LOW 100 2.950 80 60 2.955 CL = VDD, CB/CL BIT = LOW 40 2.945 -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) -60 -40 -20 0 20 40 60 80 100120140 TEMPERATURE (°C) 30115988 30115990 PIN Measurement Accuracy (VIN - SENSE = 50 mV) 0.5 1.0 0.4 0.8 0.3 0.6 PIN ERROR (% OF FSR) IIN ERROR ( % OF FSR) IIN Measurement Accuracy (VIN - SENSE = 50 mV) 0.2 0.1 0.0 -0.1 -0.2 -0.3 0.4 0.2 0.0 -0.2 -0.4 -0.6 -0.4 -0.8 -0.5 -1.0 -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE ( °C) -60 -40 -20 0 20 40 60 80 100 120 140 TEMPERATURE (°C) 301159a8 301159a9 9 www.national.com 300 Startup (Insertion Delay) Rs = 3 mΩ Rs = 5 mΩ Rs = 10 mΩ Rs = 20 mΩ 250 PMOSFET(LIM) (W) LM5066 MOSFET Power Dissipation Limit vs. RPWR and RS (VIN = 48V) 200 150 100 50 30115991 100 ms/DIV 0 0 25 50 75 100 RPWR (kΩ) 125 150 301159f2 Startup (Short circuit VOUT) Startup (1A Load) 30115993 30115992 1s/DIV 50 ms/DIV Startup (UVLO/EN, OVLO) Startup (PGD) 30115994 30115995 200 ms/DIV www.national.com 200 ms/DIV 10 LM5066 Current Limit Event (CL = VDD) Circuit Breaker Event (CL = VDD) 30115996 30115997 2 ms/DIV 500 µs/DIV Retry Event (RETRY = GND) Latch Off (RETRY = VDD) 30115999 200 ms/DIV 30115998 500 ms/DIV 11 www.national.com LM5066 Block Diagram 30115910 RETRY pin. Once started, the number of retries can be set to none, 1, 2, 4, 8, 16, or infinite. The circuit breaker function quickly switches off the series pass device upon detection of a severe over-current condition. Programmable under-voltage lockout (UVLO) and over-voltage lockout (OVLO) circuits shut down the LM5066 when the system input voltage is outside the desired operating range. The telemetry capability of the LM5066 provides intelligent monitoring of the input voltage, output voltage, input current, input power, temperature, and an auxiliary input. The LM5066 also provides a peak capture of the input power and programmable hardware averaging of the input voltage, current, power, and output voltage. Warning thresholds which trigger the SMBA pin may be programmed for input and output voltage, current, power and temperature via the PMBus interface. Additionally, the LM5066 is capable of detecting damage to the external MOSFET, Q1. Functional Description The inline protection functionality of the LM5066 is designed to control the in-rush current to the load upon insertion of a circuit card into a live backplane or other “hot” power source, thereby limiting the voltage sag on the backplane’s supply voltage, and the dV/dt of the voltage applied to the load. The effects on other circuits in the system are minimized by preventing possible unintended resets. A controlled shutdown when the circuit card is removed can also be implemented using the LM5066. In addition to a programmable current limit, the LM5066 monitors and limits the maximum power dissipation in the series pass device to maintain operation within the device Safe Operating Area (SOA). Either current limiting or power limiting for an extended period of time results in the shutdown of the series pass device. In this event, the LM5066 can latch off or repetitively retry based on the hardware setting of the www.national.com 12 LM5066 30115911 FIGURE 1. Typical Application Circuit As the voltage at the OUT pin increases, the LM5066 monitors the drain current and power dissipation of MOSFET Q1. Inrush current limiting and/or power limiting circuits actively control the current delivered to the load. During the in-rush limiting interval (t2 in Figure 2) an internal 75 µA fault timer current source charges CT. If Q1’s power dissipation and the input current reduce below their respective limiting thresholds before the TIMER pin reaches 3.9V, the 75 µA current source is switched off, and CT is discharged by the internal 2.5 µA current sink (t3 in Figure 2). The in-rush limiting will no longer engage unless a current-limit condition occurs. If the TIMER pin voltage reaches 3.9V before in-rush current limiting or power limiting ceases during t2, a fault is declared and Q1 is turned off. See the Fault Timer & Restart section for a complete description of the fault mode. The LM5066 will assert the SMBA pin after the input voltage has exceeded its POR threshold to indicate that the volatile memory and device settings are in their default state. The CONFIG_PRESET bit within the STATUS_MFR_SPECIFIC register (80h) indicates default configuration of warning thresholds and device operation and will remain high until a CLEAR_FAULTS command is received. Power Up Sequence The VIN operating range of the LM5066 is 10V to 80V, with a transient capability to 100V. Referring to Figure 1 and Figure 2, as the voltage at VIN initially increases, the external Nchannel MOSFET (Q1) is held off by an internal 115 mA pulldown current at the GATE pin. The strong pull-down current at the GATE pin prevents an inadvertent turn-on as the MOSFET’s gate-to-drain (Miller) capacitance is charged. Additionally, the TIMER pin is initially held at ground. When the VIN voltage reaches the POR threshold the insertion time begins. During the insertion time, the capacitor at the TIMER pin (CT) is charged by a 4.8 µA current source, and Q1 is held off by a 4.2 mA pull-down current at the GATE pin regardless of the input voltage. The insertion time delay allows ringing and transients at VIN to settle before Q1 is enabled. The insertion time ends when the TIMER pin voltage reaches 3.9V. CT is then quickly discharged by an internal 1.5 mA pull-down current. The GATE pin then switches on Q1 when VIN exceeds the UVLO threshold. If VIN is above the UVLO threshold at the end of the insertion time, Q1 the GATE pin charge pump sources 20 µA to charge the gate capacitance of Q1. The maximum voltage from the gate to source of the Q1 is limited by an internal 16.5V zener diode. 13 www.national.com LM5066 30115913 FIGURE 2. Power Up Sequence (Current Limit Only) or an automatic retry is attempted (RETRY pin to GROUND or floating). See the Fault Timer & Restart section. If the system input voltage falls below the UVLO threshold, or rises above the OVLO threshold, the GATE pin is pulled low by the 4.2 mA pull-down current to switch off Q1. Gate Control A charge pump provides the voltage at the GATE pin to enhance the N-Channel MOSFET’s gate (Q1). During normal operating conditions (t3 in Figure 2) the gate of Q1 is held charged by an internal 20 µA current source. The charge pump peak voltage is roughly 13.5V, which will force a VGS across Q1 of 13.5V under normal operation. When the system voltage is initially applied, the GATE pin is held low by a 115 mA pull-down current. This helps prevent an inadvertent turnon of Q1 through its drain-gate capacitance as the applied system voltage increases. During the insertion time (t1 in Figure 2) the GATE pin is held low by a 4.2 mA pull-down current. This maintains Q1 in the off-state until the end of t1, regardless of the voltage at VIN or UVLO. Following the insertion time, during t2 in Figure 2 the gate voltage of Q1 is modulated to keep the current or power dissipation level from exceeding the programmed levels. While in the current or power limiting mode, the TIMER pin capacitor is charging. If the current and power limiting cease before the TIMER pin reaches 3.9V the TIMER pin capacitor then discharges, and the circuit begins normal operation. If the in-rush limiting condition persists such that the TIMER pin reached 3.9V during t2, the GATE pin is then pulled low by the 4.2 mA pull-down current. The GATE pin is then held low until either a power up sequence is initiated (RETRY pin to VDD), www.national.com Current Limit The current limit threshold is reached when the voltage across the sense resistor RS (VIN to SENSE) exceeds the internal voltage limit of 26 mV or 50 mV depending on whether the CL pin is connected to VDD or GND, respectively. In the current limiting condition, the GATE voltage is controlled to limit the current in MOSFET Q1. While the current limit circuit is active, the fault timer is active as described in the Fault Timer & Restart section. If the load current falls below the current limit threshold before the end of the Fault Timeout Period, the LM5066 resumes normal operation. If the current limit condition persists for longer than the Fault Timeout Period set by CT, the IIN OC Fault bit in the STATUS_INPUT (7Ch) register, the INPUT bit in the STATUS_WORD (79h) register, and IIN_OC/PFET_OP_FAULT bit in the DIAGNOSTIC_WORD (E1h) register will be toggled high and SMBA pin will be asserted. SMBA toggling can be disabled using the ALERT_MASK (D8h) register. For proper operation, the RS resistor value should be no higher than 200 mΩ. Higher val14 Fault Timer & Restart When the current limit or power limit threshold is reached during turn-on, or as a result of a fault condition, the gate-tosource voltage of Q1 is modulated to regulate the load current and power dissipation in Q1. When either limiting function is active, a 75 µA fault timer current source charges the external capacitor (C T) at the TIMER pin as shown in Figure 2 (Fault Timeout Period). If the fault condition subsides during the Fault Timeout Period before the TIMER pin reaches 3.9V, the LM5066 returns to the normal operating mode and CT is discharged by the 1.5 mA current sink. If the TIMER pin reaches 3.9V during the Fault Timeout Period, Q1 is switched off by a 4.2 mA pull-down current at the GATE pin. The subsequent restart procedure then depends on the selected retry configuration. If the RETRY pin is high, the LM5066 latches the GATE pin low at the end of the Fault Timeout Period. CT is then discharged to ground by the 2.5 µA fault current sink. The GATE pin is held low by the 4.2 mA pull-down current until a power up sequence is externally initiated by cycling the input voltage (VIN), or momentarily pulling the UVLO/EN pin below its threshold with an open-collector or open-drain device as shown in Figure 3. The voltage at the TIMER pin must be <0.3V for the restart procedure to be effective. The TIMER_LATCHED_OFF bit in the DIAGNOSTIC_WORD (E1h) register will remain high while the latched off condition persists. Circuit Breaker If the load current increases rapidly (e.g., the load is short circuited) the current in the sense resistor (RS) may exceed the current limit threshold before the current limit control loop is able to respond. If the current exceeds 1.94x or 3.87x (CL = GND) the current limit threshold, Q1 is quickly switched off by the 115 mA pull-down current at the GATE pin, and a Fault Timeout Period begins. When the voltage across RS falls below the circuit breaker (CB) threshold, the 115 mA pull-down current at the GATE pin is switched off, and the gate voltage of Q1 is then determined by the current limit or the power limit functions. If the TIMER pin reaches 3.9V before the current limiting or power limiting condition ceases, Q1 is switched off by the 4.2 mA pull-down current at the GATE pin as described in the Fault Timer & Restart section. A circuit breaker event will cause the CIRCUIT BREAKER FAULT bit in the STATUS_MFR_SPECIFIC (80h) and DIAGNOSTIC_WORD (E1h) registers to be toggled high and SMBA pin will be asserted unless this feature is disabled using the ALERT_MASK (D8h) register. The circuit breaker pin configuration may be overridden by setting appropriate bits in the DEVICE_SETUP (D9h) register. Power Limit An important feature of the LM5066 is the MOSFET power limiting. The Power Limit function can be used to maintain the maximum power dissipation of MOSFET Q1 within the device SOA rating. The LM5066 determines the power dissipation in Q1 by monitoring its drain-source voltage (SENSE to OUT), and the drain current through the RS (VIN to SENSE). The product of the current and voltage is compared to the power limit threshold programmed by the resistor at the PWR pin. If the power dissipation reaches the limiting threshold, the GATE voltage is modulated to regulate the current in Q1. While the power limiting circuit is active, the fault timer is active as described in the Fault Timer & Restart section. If the power limit condition persists for longer than the Fault Timeout Period set by the timer capacitor, CT, the IIN OC Fault bit in the STATUS_INPUT (7Ch) register, the INPUT bit in the STATUS_WORD (79h) register, and the IIN_OC/ PFET_OP_FAULT bit in the DIAGNOSTIC_WORD (E1h) register will be toggled high and SMBA pin will be asserted unless this feature is disabled using the ALERT_MASK (D8h) register. 30115915 FIGURE 3. Latched Fault Restart Control The LM5066 provides an automatic restart sequence which consists of the TIMER pin cycling between 3.9V and 1.1V seven times after the Fault Timeout Period, as shown in Figure 4. The period of each cycle is determined by the 75 µA charging current, and the 2.5 µA discharge current, and the value of the capacitor CT. When the TIMER pin reaches 0.3V during the eighth high-to-low ramp, the 20 µA current source at the GATE pin turns on Q1. If the fault condition is still present, the Fault Timeout Period and the restart sequence repeat. The RETRY pin allows selecting no retries or infinite retries. Finer control of the retry behavior can be achieved through the DEVICE_SETUP (D9h) register. Retry counts of 0, 1, 2, 4, 8, 16 or infinite may be selected by setting the appropriate bits in the DEVICE_SETUP (D9h) register. 15 www.national.com LM5066 ues may create instability in the current limit control loop. The current limit threshold pin value may be overridden by setting appropriate bits in the DEVICE_SETUP register (D9h). LM5066 30115916 FIGURE 4. Restart Sequence register and the VIN_OVERVOLTAGE_FAULT bit in the DIAGNOSTIC_WORD (E1h) register. The SMBA pin will be pulled low unless this feature is disabled using the ALERT_MASK (D8h) register. See the Applications Section for a procedure to calculate the threshold setting resistor values. Under-Voltage Lockout (UVLO) The series pass MOSFET (Q1) is enabled when the input supply voltage (VIN) is within the operating range defined by the programmable under-voltage lockout (UVLO) and overvoltage lockout (OVLO) levels. Typically the UVLO level at VIN is set with a resistor divider (R1-R3) as shown in Figure 5. Refering to the Block Diagram when VIN is below the UVLO level, the internal 20 µA current source at UVLO is enabled, the current source at OVLO is off, and Q1 is held off by the 4.2 mA pull-down current at the GATE pin. As VIN is increased, raising the voltage at UVLO above its threshold the 20 µA current source at UVLO is switched off, increasing the voltage at UVLO, providing hysteresis for this threshold. With the UVLO/EN pin above its threshold, Q1 is switched on by the 20 µA current source at the GATE pin if the insertion time delay has expired. See the Applications Section for a procedure to calculate the values of the threshold setting resistors (R1-R3). The minimum possible UVLO level at VIN can be set by connecting the UVLO/EN pin to VIN. In this case Q1 is enabled after the insertion time when the voltage at VIN reaches the POR threshold. After power up an UVLO condition will cause the INPUT bit in the STATUS_WORD (79h) register, the VIN_UV_FAULT bit in the STATUS_INPUT (7Ch) register, and the VIN_UNDERVOLTAGE_FAULT bit in the DIAGNOSTIC_WORD (E1h) registers to be toggled high and SMBA pin will be pulled low unless this feature is disabled using the ALERT_MASK (D8h) register. Shutdown Control The load current can be remotely switched off by taking the UVLO/EN pin below its threshold with an open collector or open drain device, as shown in Figure 5. Upon releasing the UVLO/EN pin the LM5066 switches on the load current with in-rush current and power limiting. 30115917 FIGURE 5. Shutdown Control Over-Voltage Lockout (OVLO) Power Good Pin The series pass MOSFET (Q1) is enabled when the input supply voltage (VIN) is within the operating range defined by the programmable under-voltage lockout (UVLO) and overvoltage lockout (OVLO) levels. If VIN raises the OVLO pin voltage above its threshold, Q1 is switched off by the 4.2 mA pull-down current at the GATE pin, denying power to the load. When the OVLO pin is above its threshold, the internal 21 µA current source at OVLO is switched on, raising the voltage at OVLO to provide threshold hysteresis. When VIN is reduced below the OVLO level Q1 is re-enabled. An OVLO condition will toggle the VIN_OV_FAULT bit in the STATUS_INPUT (7Ch) register, the INPUT bit in the STATUS_WORD (79h) www.national.com The Power Good indicator pin (PGD) is connected to the drain of an internal N-channel MOSFET capable of sustaining 80V in the off-state, and transients up to 100V. An external pull-up resistor is required at PGD to an appropriate voltage to indicate the status to downstream circuitry. The off-state voltage at the PGD pin can be higher or lower than the voltages at VIN and OUT. PGD is switched high when the voltage at the FB pin exceeds the PGD threshold voltage. Typically the output voltage threshold is set with a resistor divider from output to feedback, although the monitored voltage need not be the output voltage. Any other voltage can be monitored as long 16 Erroneous temperature measurements may result when the device input voltage is below the minimum operating voltage (10V), due to VREF dropping out below the nominal voltage (2.97V). At higher ambient temperatures, this measurement could read a value higher than the OT_FAULT_LIMIT, and will trigger a fault, disabling Q1. In this case, the faults should be removed and the device reset by writing a 0h, followed by an 80h to the OPERATION (03h) register. Damaged MOSFET Detection The LM5066 is able to detect whether the external MOSFET, Q1, is damaged under certain conditions. If the voltage across the sense resistor exceeds 4mV while the GATE voltage is low or the internal logic indicates that the GATE should be low, the EXT_MOSFET_SHORTED bit in the STATUS_MFR_SPECIFIC (80h) and DIAGNOSTIC_WORD (E1h) registers will be toggled high and the SMBA pin will be asserted unless this feature is disabled using the ALERT_MASK register (D8h). This method effectively determines whether Q1 is shorted because of damage present between the drain and gate and/or drain and source. VDD Sub-Regulator The LM5066 contains an internal linear sub-regulator which steps down the input voltage to generate a 4.9V rail used for powering low voltage circuitry. The VDD sub-regulator should be used as the pull-up supply for the CL, RETRY, ADR2, ADR1, ADR0 pins if they are to be tied high. It may also be used as the pull-up supply for the PGD and the SMBus signals (SDA, SCL, SMBA). The VDD sub-regulator is not designed to drive high currents and should not be loaded with other integrated circuits. The VDD pin is current limited to 30mA in order to protect the LM5066 in the event of a short. The subregulator requires a ceramic bypass capacitance having a value of 1 µF or greater to be placed as close to the VDD pin as the PCB layout allows. Enabling/Disabling and Resetting The output can be disabled at any time during normal operation by either pulling the UVLO/EN pin to below its threshold or the OVLO pin above its threshold, causing the GATE voltage to be forced low with a pulldown strength of 4.2mA. Toggling the UVLO/EN pin will also reset the LM5066 from a latched-off state due to an over-current or over-power limit condition which has caused the maximum allowed number of retries to be exceeded. While the UVLO/EN or OVLO pins can be used to disable the output they have no effect on the volatile memory or address location of the LM5066. User stored values for address, device operation, and warning and fault levels programmed via the SMBus are preserved while the LM5066 is powered regardless of the state of the UVLO/ EN and OVLO pins.The output may also be enabled or disabled by writing 80h or 0h to the OPERATION (03h) register. To re-enable after a fault, the fault condition should be cleared and the OPERATION (03h) register with 0h and then 80h. The SMBus address of the LM5066 is captured based on the states of the ADR0, ADR1, and ADR2 pins (GND, NC, VDD) during turn on and is latched into a volatile register once VDD has exceeded its POR threshold of 4.1V. Reassigning or postponing the address capture is accomplished by holding the VREF pin to ground. Pulling the VREF pin low will also reset the logic and erase the volatile memory of the LM5066. Once released, the VREF pin will charge up to its final value and the address will be latched into a volatile register once the voltage at the VREF exceeds 2.55V. Remote Temperature Sensing The LM5066 is designed to measure temperature remotely using an MMBT3904 NPN transistor. The base and collector of the MMBT3904 should be connected to the DIODE pin and the emitter to the LM5066 ground. Place the MMBT3904 near the device that requires temperature sensing. If the temperature of the hot swap pass MOSFET, Q1, is to be measured, the MMBT3904 should be placed as close to Q1 as the layout allows. The temperature is measured by means of a change in the diode voltage in response to a step in current supplied by the DIODE pin. The DIODE pin sources a constant 9.4 µA but pulses 250 µA once every millisecond in order to measure the diode temperature. Care must be taken in the PCB layout to keep the parasitic resistance between the DIODE pin and the MMBT3904 low so as not to degrade the measurement. Additionally, a small 1000 pF bypass capacitor should be placed in parallel with the MMBT3904 to reduce the effects of noise. The temperature can be read using the READ_TEMPERATURE_1 PMBus command (8Dh). The default limits of the LM5066 will cause SMBA pin to be pulled low if the measured temperature exceeds 125°C and will disable Q1 if the temperature exceeds 150°C. These thresholds can be reprogrammed via the PMBus interface using the OT_WARN_LIMIT (51h) and OT_FAULT_LIMIT (4Fh) commands. If the temperature measurement and protection capability of the LM5066 are not used, the DIODE pin should be grounded. 17 www.national.com LM5066 as the voltage at the FB pin does not exceed its maximum rating. Referring to the Block Diagram, when the voltage at the FB pin is below its threshold, the 20 µA current source at FB is disabled. As the output voltage increases, taking FB above its threshold, the current source is enabled, sourcing current out of the pin, raising the voltage at FB to provide threshold hysteresis. The PGD output is forced low when either the UVLO/EN pin is below its threshold or the OVLO pin is above its threshold. The status of the PGD pin can be read via the PMBus interface in either the STATUS_WORD (79h) or DIAGNOSTIC_WORD (E1h) registers. LM5066 Application Section 30115901 FIGURE 6. Typical Application Circuit this data sheet, but should be verified experimentally. Review the resulting insertion time and the restart timing if retry is enabled. UVLO, OVLO: Choose option A, B, C, or D from the UVLO, OVLO section of the Application Information to set the UVLO and OVLO thresholds and hysteresis. Use the procedure for the appropriate option to determine the resistor values at the UVLO/EN and OVLO pins. Power Good: Choose the appropriate output voltage and calculate the required resistor divider from the output voltage to the FB pin. Choose either VDD or OUT to connect a properly sized pull-up resistor for the Power Good output (PGD). Refer to Programming Guide section: After all hardware design is complete, refer to the programming guide for a step by step procedure regarding software. DESIGN-IN PROCEDURE Refer to Figure 6 for Typical Application Circuit. The following is the step-by-step procedure for hardware design of the LM5066. This procedure refers to section numbers that provide detailed information on the following design steps. The recommended design-in procedure is as follows: MOSFET Selection: Determine MOSFET based on breakdown voltage, current and power ratings. Current Limit, RS: Determine the current limit threshold (ILIM). This threshold must be higher than the normal maximum load current, allowing for tolerances in the current sense resistor value and the LM5066 Current Limit threshold voltage. Use equation 1 to determine the value for RS. Power Limit Threshold: Determine the maximum allowable power dissipation for the series pass MOSFET (Q1), using the device’s SOA information. Use equation 2 to determine the value for RPWR. Note that many MOSFET manufacturers do not accurately specify the device SOA so it is usually beneficial to choose a conservative value when selecting RPWR. Turn-on Time and TIMER Capacitor, CT: Determine the value for the timing capacitor at the TIMER pin (CT) using equation 7 and 8. The fault timeout period (tFAULT) MUST be longer than the circuit’s turn-on time. The turn-on time can be estimated using the equations in the TURN-ON TIME section of www.national.com MOSFET SELECTION It is recommended that the external MOSFET (Q1) selection is based on the following criteria: - The BVDSS rating should be greater than the maximum system voltage (VIN), plus ringing and transients which can occur at VIN when the circuit card, or adjacent cards, are inserted or removed. 18 (1) where ILIM is the desired current limit threshold. If the voltage across RS reaches VCL, the current limit circuit modulates the gate of Q1 to regulate the current at ILIM. While the current limiting circuit is active, the fault timer is active as described in the Fault Timer & Restart section. For proper operation, RS must be less than 200 mΩ. VCL can be set to either 26 mV or 50 mV via hardware and/or software. This setting defaults to use of CL pin which, when connected to VDD is 26 mV, or grounded is 50 mV. The value, when powered, can be set via the PMBus with the MFR_SPECIFIC_DEVICE_SETUP command, which defaults to the 26 mV setting. Once the desired setting is known, calculate the shunt based on that input voltage and maximum current. While the maximum load current in normal operation can be used to determine the required power rating for resistor RS, basing it on the current limit value provides a more reliable design since the circuit can operate near the current limit threshold continuously. The resistor’s surge capability must also be considered since the circuit breaker threshold is 1.94 or 3.87 times the current limit threshold. Connections from RS to the LM5066 should be made using Kelvin techniques. In the suggested layout of Figure 7 the small pads at the lower corners of the sense resistor connect only to the sense resistor terminals, and not to the traces carrying the high current. With this technique, only the voltage across the sense resistor is applied to VIN_K and SENSE, eliminating the voltage drop across the high current solder connections. CURRENT LIMIT (RS) The LM5066 monitors the current in the external MOSFET Q1 by measuring the voltage across the sense resistor (RS), connected from VIN to SENSE. The required resistor value is calculated from: 30115919 FIGURE 7. Sense Resistor Connections where PMOSFET(LIM) is the desired power limit threshold for Q1, and RS is the current sense resistor described in the Current Limit section. For example, if RS is 5 mΩ, VIN = 48V, and the desired power limit threshold is 50W, RPWR calculates to 24.9 kΩ. If Q1’s power dissipation reaches the threshold Q1’s gate is modulated to regulate the load current, keeping Q1’s power from exceeding the threshold. For proper operation of the power limiting feature, RPWR must be ≤150 kΩ. While the power limiting circuit is active, the fault timer is active as described in the Fault Timer & Restart section. Typically, power limit is reached during startup, or if the output voltage falls due POWER LIMIT THRESHOLD The LM5066 determines the power dissipation in the external MOSFET (Q1) by monitoring the drain current (the current in RS) and the VDS of Q1 (SENSE to OUT pins). The resistor at the PWR pin (RPWR) sets the maximum power dissipation for Q1, and is calculated from the following equation: (2) 19 www.national.com LM5066 - The maximum continuous current rating should be based on the current limit threshold (e.g., 26 mV/RS for CL = VDD), not the maximum load current, since the circuit can operate near the current limit threshold continuously. - The Pulsed Drain Current spec (IDM) must be greater than the current threshold for the circuit breaker function (48/96/193 mV/RS, depending on CL and CB configuration). - The SOA (Safe Operating Area) chart of the device, and the thermal properties, should be used to determine the maximum power dissipation threshold set by the RPWR resistor. The programmed maximum power dissipation should have a reasonable margin from the maximum power defined by the MOSFET’s SOA curve. If the device is set to infinitely retry, the MOSFET will be repeatedly stressed during fault restart cycles. The MOSFET manufacturer should be consulted for guidelines. - RDS(on) should be sufficiently low such that the power dissipation at maximum load current (ILIM2 x RDS(on)) does not raise its junction temperature above the manufacturer’s recommendation. - The gate-to-source voltage provided by the LM5066 can be as high as 16.5V, limited by the internal zener diode from GATE to OUT. Q1 must be able to tolerate this voltage for its VGS rating. An additional zener diode can be added from GATE to OUT to lower this voltage and limit the peak VGS. The zener diode’s forward current rating must be at least 110 mA to conduct the GATE pull-down current when a circuit breaker condition is detected. LM5066 the current limit threshold is less than the current defined by the power limit threshold at maximum VDS the circuit operates only at the current limit threshold during turn-on. Referring to Figure 8A, as the load current reaches ILIM, the gate-to-source voltage is controlled at VGSL to maintain the current at ILIM. As the output voltage reaches its final value (VDS ≊ 0V) the drain current reduces to its normal operating value. The time for the OUT pin voltage to transition from zero volts to VIN is equal to: to a severe overload or short circuit. The programmed maximum power dissipation should have a reasonable margin from the maximum power defined by the SOA chart, especially if retry is enabled, because the MOSFET will be repeatedly stressed during fault restart cycles. The MOSFET manufacturer should be consulted for guidelines. If the application does not require use of the power limit function the PWR pin can be left open. The accuracy of the power limit function at turn-on may degrade if a very low power dissipation limit is set. The reason for this caution is that the voltage across the sense resistor, which is monitored and regulated by the power limit circuit, is lowest at turn-on when the regulated current is at a minimum. The voltage across the sense resistor during power limit can be expressed as follows: (4) where CL is the load capacitance. For example, if VIN = 48V, CL = 200 µF, and ILIM = 5A, tON calculates to 12 ms. The maximum instantaneous power dissipated in the MOSFET is 12W. This calculation assumes the time from t1 to t2 in Figure 9(a) is small compared to tON, the load does not draw any current until after the output voltage has reached its final value, and PGD switches high (Figure 8A). The Fault Timeout Period must be set longer than tON to prevent a fault shutdown before the turn-on sequence is complete. If the load draws current during the turn-on sequence (Figure 8B), the turn-on time is longer than the above calculation, and is approximately equal to: (3) where ILIM is the current in RS, and VDS is the voltage across Q1. For example, if the power limit is set at 75W with RS = 5 mΩ, and VDS = 48V the sense resistor voltage calculates to 7.8 mV, which is comfortably regulated by the LM5066. However, if the power limit is set lower (e.g., 25W), the sense resistor voltage calculates to 2.6 mV. At this low level noise and offsets within the LM5066 may degrade the power limit accuracy. To maintain accuracy, the sense resistor voltage should not be less than 3 mV. (5) TURN-ON TIME The output turn-on time depends on whether the LM5066 operates in current limit, or in both power limit and current limit, during turn-on. A) Turn-on with current limit only: The current limit threshold (ILIM) is determined by the current sense resistor (RS). If where RL is the load resistance. The Fault Timeout Period must be set longer than tON to prevent a fault shutdown before the turn-on sequence is complete. 30115922 30115923 A. No Load Current During Turn-On B. Load Draws Current During Turn-On FIGURE 8. Current During Turn-On B) Turn-On with Power Limit and Current Limit: The maximum allowed power dissipation in Q1 (PMOSFET(LIM)) is defined by the resistor at the PWR pin, and the current sense resistor RS. See the Power Limit Threshold section. If the current limit threshold (ILIM) is higher than the current defined by the power limit threshold at maximum VDS (PMOSFET(LIM)/VIN) the circuit operates initially in the power limit mode when the VDS of Q1 is high, and then transitions to current limit mode as the current increases to ILIM and VDS decreases. Assuming the load (RL) is not connected during turn-on, the time for the www.national.com output voltage to reach its final value is approximately equal to: (6) For example, if VIN = 48V, CL = 200 µF, ILIM = 1A, and PMOSFET (LIM) = 10W, tON calculates to ≊24 ms, and the initial current level (IP) is approximately 0.208A. The Fault Timeout Period must be set longer than tON. 20 LM5066 30115925 FIGURE 9. MOSFET Power Up Waveforms expires, a restart sequence starts as described below (Restart Timing). During consecutive cycles of the restart sequence, the fault timeout period is shorter than the initial fault time out period described above by approximately 8% since the voltage at the TIMER pin starts ramping up from 0.3V rather than ground. Since the LM5066 normally operates in power limit and/or current limit during a power up sequence, the Fault Timeout Period MUST be longer than the time required for the output voltage to reach its final value. See the Turn-On Time section. C) Restart Timing For the LM5066, after the Fault Timeout Period described above, CT is discharged by the 2.5 µA current sink to 1.1V. The TIMER pin then cycles through seven additional charge/discharge cycles between 1.1V and 3.9V as shown in Figure 4. The restart time ends when the TIMER pin voltage reaches 0.3V during the final high-to-low ramp. The restart time, after the Fault Timeout Period, is equal to: TIMER CAPACITOR, CT The TIMER pin capacitor (CT) sets the timing for the insertion time delay, fault timeout period, and the restart timing of the LM5066. A) Insertion Delay - Upon applying the system voltage (VIN) to the circuit, the external MOSFET (Q1) is held off during the insertion time (t1 in Figure 2) to allow ringing and transients at VIN to settle. Since each backplane’s response to a circuit card plug-in is unique, the worst case settling time must be determined for each application. The insertion time starts when VIN reaches the POR threshold, at which time the internal 4.8 µA current source charges CT from 0V to 3.9V. The required capacitor value is calculated from: (7) For example, if the desired insertion delay is 250 ms, CT calculates to 0.3 µF. At the end of the insertion delay, CT is quickly discharged by a 1.5 mA current sink. B) Fault Timeout Period - During in-rush current limiting or upon detection of a fault condition where the current limit and/ or power limit circuits regulate the current through Q1, the fault timer current source (75 µA) is switched on to charge CT. The Fault Timeout Period is the time required for the TIMER pin voltage to reach 3.9V, at which time Q1 is switched off. The required capacitor value for the desired Fault Timeout Period tFAULT is calculated from: (9) = CT x 9.5 x 106 (10) For example, if CT = 0.8 µF, tRESTART = 7.9 seconds. At the end of the restart time, Q1 is switched on. If the fault is still present, the fault timeout and restart sequence repeats. The on-time duty cycle of Q1 is approximately 0.5% in this mode. UVLO, OVLO By programming the UVLO and OVLO thresholds the LM5066 enables the series pass device (Q1) when the input supply voltage (VIN) is within the desired operational range. If VIN is below the UVLO threshold, or above the OVLO threshold, Q1 is switched off, denying power to the load. Hysteresis is provided for each threshold. Option A: The configuration shown in Figure 10 requires three resistors (R1-R3) to set the thresholds. (8) For example, if the desired Fault Timeout Period is 15 ms, CT calculates to 0.3 µF. CT is discharged by the 2.5 µA current sink at the end of the Fault Timeout Period. After the Fault Timeout Period, if retry is disabled, the LM5066 latches the GATE pin low until a power up sequence is initiated by external circuitry. When the Fault Timeout Period of the LM5066 21 www.national.com LM5066 30115929 FIGURE 10. UVLO and OVLO Thresholds Set By R1-R3 The procedure to calculate the resistor values is as follows: - Choose the upper UVLO threshold (VUVH), and the lower UVLO threshold (VUVL). - Choose the upper OVLO threshold (VOVH). - The lower OVLO threshold (VOVL) cannot be chosen in advance in this case, but is determined after the values for R1R3 are determined. If VOVL must be accurately defined in addition to the other three thresholds, see Option B below. The resistors are calculated as follows: (16) (17) The lower OVLO threshold calculates to 55.6V, and the OVLO hysteresis is 4.4V. Note that the OVLO hysteresis is always slightly greater than the UVLO hysteresis in this configuration. When the R1-R3 resistor values are known, the threshold voltages and hysteresis are calculated from the following: (11) (18) (12) (19) VUV(HYS) = R1 x 20µA (13) The lower OVLO threshold is calculated from: (20) (14) (21) As an example, assume the application requires the following thresholds: VUVH = 36V, VUVL = 32V, VOVH = 60V. VOV(HYS) = (R1 + R2) x 21µA Option B: If all four thresholds must be accurately defined, the configuration in Figure 11 can be used. (15) www.national.com 22 LM5066 30115941 FIGURE 11. Programming the Four Thresholds The four resistor values are calculated as follows: - Choose the upper and lower UVLO thresholds (VUVH) and (VUVL). R3 = 190 kΩ, R4 = 8.1 kΩ When the R1-R4 resistor values are known, the threshold voltages and hysteresis are calculated from the following: (22) (26) (23) (27) - Choose the upper and lower OVLO threshold (VOVH) and (VOVL). VUV(HYS) = R1 x 20 µA (28) (24) (29) (25) Option C: The minimum UVLO level is obtained by connecting the UVLO/EN pin to VIN as shown in Figure 12. Q1 is switched on when the VIN voltage reaches the POREN threshold (≊8.6V). The OVLO thresholds are set using R3, R4. Their values are calculated using the procedure in Option B. As an example, assume the application requires the following thresholds: VUVH = 36V, VUVL = 32V, VOVH = 60V, and VOVL = 56V. Therefore VUV(HYS) = 4V, and VOV(HYS) = 4V. The resistor values are: R1 = 200 kΩ, R2 = 16.8 kΩ 30115950 FIGURE 12. UVLO = POREN Option D: The OVLO function can be disabled by grounding the OVLO pin. The UVLO thresholds are set as described in Option B or Option C. 23 www.national.com LM5066 POWER GOOD PIN When the voltage at the FB pin increases above its threshold the internal pulldown acting on the PGD pin is disabled allowing PGD to rise to VPGD through the pull-up resistor, RPG, as shown in Figure 14. The pull-up voltage (VPGD) can be as high as 80V, and can be higher or lower than the voltages at VIN and OUT. VDD is a convenient choice for VPGD as it allows interface to low voltage logic and avoids glitching on PGD during power-up. If a delay is required at PGD, suggested circuits are shown in Figure 15. In Figure 15A, capacitor CPG adds delay to the rising edge, but not to the falling edge. In Figure 15B, the rising edge is delayed by RPG1 + RPG2 and CPG, while the falling edge is delayed a lesser amount by RPG2 and CPG. Adding a diode across RPG2 (Figure 15C) allows for equal delays at the two edges, or a short delay at the rising edge and a long delay at the falling edge. Setting the output threshold for the PGD pin requires two resistors (R4, R5) as shown in Figure 13. While monitoring the output voltage is shown in Figure 13, R4 can be connected to any other voltage which requires monitoring. The resistor values are calculated as follows: Choose the upper and lower threshold (VPGDH) and (VPGDL) at VOUT. 301159a5 FIGURE 13. Programming the PGD Threshold As an example, assume the application requires the following thresholds: VPGDH = 40V, and VPGDL = 38V. Therefore VPGD (HYS) = 2V. The resistor values are: R4 = 100 kΩ, R5 = 6.55 kΩ When the R4 and R5 resistor values are known, the threshold voltages and hysteresis are calculated from the following: 30115951 FIGURE 14. Power Good Output 30115952 FIGURE 15. Adding Delay to the Power Good Output Pin www.national.com 24 30115954 FIGURE 16. Output Diode Required for Inductive Loads cant current flow through the diodes, which can result in device failure. - The sense resistor (RS) should be placed close to the LM5066. A trace should connect the VIN pad and Q1 pad of the sense resistor to VIN_K and SENSE pins, respectively. Connect RS using the Kelvin techniques shown in Figure 7. - The high current path from the board’s input to the load (via Q1), and the return path, should be parallel and close to each other to minimize loop inductance. - The AGND and GND connections should be connected at the pins of the device.The ground connections for the various components around the LM5066 should be connected directly to each other, and to the LM5066’s GND and AGND pin connection, and then connected to the system ground at one point. Do not connect the various component grounds to each other through the high current ground line. - Provide adequate thermal sinking for the series pass device (Q1) to help reduce stresses during turn-on and turn-off. - The board’s edge connector can be designed such that the LM5066 detects via the UVLO/EN pin that the board is being removed, and responds by turning off the load before the supply voltage is disconnected. For example, in Figure 17, the voltage at the UVLO/EN pin goes to ground before VIN is removed from the LM5066 as a result of the shorter edge connector pin. When the board is inserted into the edge connector, the system voltage is applied to the LM5066’s VIN pin before the UVLO voltage is taken high, thereby allowing the LM5066 to turn on the output in a controlled fashion. PC BOARD GUIDELINES The following guidelines should be followed when designing the PC board for the LM5066: - Place the LM5066 close to the board’s input connector to minimize trace inductance from the connector to the MOSFET. - Place a TVS, Z1, directly adjacent to the VIN and GND pins of the LM5066 to help minimize voltage transients which may occur on the input supply line. The TVS should be chosen such that the peak VIN is just lower the TVS reverse-bias voltage. Transients of 20 volts or greater over the nominal input voltage can easily occur when the load current is shut off. A small capacitor may be sufficient for low current sense applications (I < 2A). It is recommended to test the VIN input voltage transient performance of the circuit by current limiting or shorting the load and measuring the peak input voltage transient. - Place a 1 µF ceramic capacitor as close as possible to VREF pin. - Place a 1 µF ceramic capacitor as close as possible to VDD pin. - Minimize the inductance between the VIN and VIN_K pins. There are anti-parallel diodes between these pins so any voltage greater than 0.3V in either polarity will cause significant current flow through the diodes, which can result in device failure. Do not place any resistors between these two nodes. - Minimize the impedance between the VIN_K and SENSE pins. There are anti-parallel diodes between these pins so any voltage greater than 0.3V in either polarity will cause signifi- 25 www.national.com LM5066 For low current solutions (<2A), a capacitor may be sufficient to limit the voltage surge, however this comes at the expense of input surge current on card insertion. If the load powered by the LM5066 hot swap circuit has inductive characteristics, a Schottky diode is required across the LM5066’s output, along with some load capacitance. The capacitance and the diode are necessary to limit the negative excursion at the OUT pin when the load current is shut off. If the OUT pin transitions more than 0.3V negative the LM5066 can be permanently damaged. See Figure 16. SYSTEM CONSIDERATIONS A) Continued proper operation of the LM5066 hot swap circuit requires a voltage clamping element present on the supply side of the connector into which the hot swap circuit is plugged in. A TVS is ideal, as depicted in Figure 16. The TVS is necessary to absorb the voltage transient generated whenever the hot swap circuit shuts off the load current. If the TVS is not present, inductance in the supply lines will generate a voltage transient at shut-off which can exceed the absolute maximum rating of the LM5066, resulting in its destruction. LM5066 30115953 FIGURE 17. Recommended Board Connector Design www.national.com 26 The device features an SMBus interface that allows the use of PMBus commands to set warn levels, error masks, and get TABLE 1. Supported PMBus Commands Code Name Function R/W Number Default Of Data Value Bytes 01h OPERATION Retrieves or stores the operation status. R/W 1 03h CLEAR_FAULTS Clears the status registers and re-arms the Black Box registers for updating. Send Byte 0 80h 19h CAPABILITY Retrieves the device capability. R 1 B0h 43h VOUT_UV_WARN_LIMIT Retrieves or stores output under-voltage warn limit threshold. R/W 2 0000h 4Fh OT_FAULT_LIMIT Retrieves or stores over temperature fault limit threshold. R/W 2 0960h (150°C) 51h OT_WARN_LIMIT Retrieves or stores over temperature warn limit threshold. R/W 2 07D0h (125°C) 57h VIN_OV_WARN_LIMIT Retrieves or stores input over-voltage warn limit threshold. R/W 2 0FFFh 58h VIN_UV_WARN_LIMIT Retrieves or stores input under-voltage warn limit threshold. R/W 2 0000h 78h STATUS_BYTE Retrieves information about the parts operating status. R 1 49h 79h STATUS_WORD Retrieves information about the parts operating status. R 2 3849h 7Ah STATUS_VOUT Retrieves information about output voltage status. R 1 00h 7Ch STATUS_INPUT Retrieves information about input status. R 1 10h 7Dh STATUS_TEMPERATURE Retrieves information about temperature status. R 1 00h 7Eh STATUS_CML Retrieves information about communications status. R 1 00h 80h STATUS_MFR_SPECIFIC Retrieves information about circuit breaker and MOSFET shorted status. R 1 10h 88h READ_VIN Retrieves input voltage measurement. R 2 0000h 8Bh READ_VOUT Retrieves output voltage measurement. R 2 0000h 8Dh READ_TEMPERATURE_1 Retrieves temperature measurement. R 2 0190h 99h MFR_ID Retrieves manufacturer ID in ASCII characters (NSC). R 3 4Eh 53h 43h 9Ah MFR_MODEL Retrieves Part number in ASCII characters. (LM5066\0\0). R 8 4Ch 4Dh 35h 30h 36h 36h 0h 0h 9Bh MFR_REVISION Retrieves part revision letter/number in ASCII (e.g., AA). R 2 41h 41h D0h MFR_SPECIFIC_00 READ_VAUX Retrieves auxiliary voltage measurement. R 2 0000h D1h MFR_SPECIFIC_01 MFR_READ_IIN Retrieves input current measurement. R 2 0000h D2h MFR_SPECIFIC_02 MFR_READ_PIN Retrieves input power measurement. R 2 0000h D3h MFR_SPECIFIC_03 MFR_IIN_OC_WARN_LIMIT Retrieves or stores input current limit warn threshold. R/W 2 0FFFh 27 www.national.com LM5066 telemetry on VIN, VOUT, IIN, VAUX, and PIN. The supported PMBus commands are shown in Table 1. PMBus™ Command Support LM5066 Number Default Of Data Value Bytes Code Name Function R/W D4h MFR_SPECIFIC_04 MFR_PIN_OP_WARN_LIMIT Retrieves or stores input power limit warn threshold. R/W 2 0FFFh D5h MFR_SPECIFIC_05 READ_PIN_PEAK Retrieves measured peak input power measurement. R 2 0000h D6h MFR_SPECIFIC_06 CLEAR_PIN_PEAK Resets the contents of the peak input power register to zero. Send Byte 0 D7h MFR_SPECIFIC_07 GATE_MASK Allows the user to disable MOSFET gate shutdown for various fault conditions. R/W 1 0000h D8h MFR_SPECIFIC_08 ALERT_MASK Retrieves or stores user SMBA fault mask. R/W 2 0820h D9h MFR_SPECIFIC_09 DEVICE_SETUP Retrieves or stores information about number of retry attempts. R/W 1 0000h DAh MFR_SPECIFIC_10 BLOCK_READ Retrieves most recent diagnostic and telemetry information in a single transaction. R 12 0190h 0000h 0000h 0000h 0000h 0000h DBh MFR_SPECIFIC_11 SAMPLES_FOR_AVG Exponent value AVGN for number of samples to be averaged (N = 2AVGN), range = 00h to 0Ch . R/W 1 00h DCh MFR_SPECIFIC_12 READ_AVG_VIN Retrieves averaged input voltage measurement. R 2 0000h DDh MFR_SPECIFIC_13 READ_AVG_VOUT Retrieves averaged output voltage measurement. R 2 0000h DEh MFR_SPECIFIC_14 READ_AVG_IIN Retrieves averaged input current measurement. R 2 0000h DFh MFR_SPECIFIC_15 READ_AVG_PIN Retrieves averaged input power measurement. R 2 0000h E0h MFR_SPECIFIC_16 BLACK_BOX_READ Captures diagnostic and telemetry information which are latched when the first SMBA event after faults are cleared. R 12 0000h 0000h 0000h 0000h 0000h 0000h MFR_SPECIFIC_17 Manufacturer-specific parallel of the STATUS_WORD to DIAGNOSTIC_WORD_READ convey all FAULT/WARN data in a single transaction. R 2 08E0h R 12 0000h 0000h 0000h 0000h 0000h 0000h E1h E2h www.national.com MFR_SPECIFIC_18 AVG_BLOCK_READ Retrieves most recent average telemetry and diagnostic information in a single transaction. 28 OPERATION (01h) The OPERATION command is a standard PMBus command that controls the MOSFET switch. This command may be used to switch the MOSFET ON and OFF under host control. It is also used to re-enable the MOSFET after a fault triggered shutdown. Writing an OFF command, followed by an ON command, will clear all faults and re-enable the device. Writing only an ON after a fault-triggered shutdown will not clear the fault registers or re-enable the device. The OPERATION command is issued with the write byte protocol. Meaning Default 80h Switch ON 80h 00h Switch OFF n/a Meaning Default 1h – 0FFFh VOUT Undervoltage Warning detection threshold 0000h (disabled) 0000h VOUT Undervoltage Warning disabled n/a OT_FAULT_LIMIT (4Fh) The OT_FAULT_LIMIT command is a standard PMBus command that allows configuring or reading the threshold for the overtemperature fault detection. Reading and writing to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read or write word protocol. If the measured temperature exceeds this value, an overtemperature fault is triggered and the MOSFET is switched off, OT FAULT flags set, and the SMBA signal asserted. After the measured temperature falls below the value in this register, the MOSFET may be switched back on with the OPERATION command. A single temperature measurement is an average of 16 round-robin cycles; therefore, the minimum temperature fault detection time is 16 ms. TABLE 2. Recognized OPERATION Command Values Value Value CLEAR FAULTS (03h) The CLEAR_FAULTS command is a standard PMBus command that resets all stored warning and fault flags and the SMBA signal. If a fault or warning condition still exists when the CLEAR_FAULTS command is issued, the SMBA signal may not clear or will re-assert almost immediately. Issuing a CLEAR_FAULTS command will not cause the MOSFET to switch back on in the event of a fault turnoff - that must be done by issuing an OPERATION command after the fault condition is cleared. This command uses the PMBus send byte protocol. TABLE 5. OT_FAULT_LIMIT Register CAPABILITY (19h) The CAPABILITY command is a standard PMBus command that returns information about the PMBus functions supported by the LM5066. This command is read with the PMBus read byte protocol. Value Meaning Default 0h – 0FFEh Overtemperature Fault threshold value 0960h (150°C) 0FFFh Overtemperature Fault detection disabled n/a TABLE 3. CAPABILITY Register Value Meaning Default B0h Supports Packet Error Check, 400Kbits/sec, Supports SMBus Alert B0h OT_WARN_LIMIT (51h) The OT_WARN_LIMIT command is a standard PMBus command that allows configuring or reading the threshold for the overtemperature warning detection. Reading and writing to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read or write word protocol. If the measured temperature exceeds this value, an Overtemperature warning is triggered and the OT WARN flags set in the respective registers and the SMBA signal asserted. A single temperature measurement is an average of 16 round-robin cycles; therefore, the minimum temperature warn detection time is 16 ms. VOUT_UV_WARN_LIMIT (58h) The VOUT_UV_WARN_LIMIT command is a standard PMBus command that allows configuring or reading the threshold for the VOUT Under-voltage Warning detection. Reading and writing to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read or write word protocol. If the measured value of VOUT falls below the value in this register, VOUT UV Warn flags are set and the SMBA signal is asserted. TABLE 6. OT_WARN_LIMIT Register 29 Value Meaning Default 0h – 0FFEh Overtemperature Warn Threshold Value 07D0h (125°C) 0FFFh Overtemperature Warn detection disabled n/a www.national.com LM5066 TABLE 4. VOUT_UV_WARN_LIMIT Register Standard PMBus Commands LM5066 to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read or write word protocol. If the measured value of VIN falls below the value in this register, VIN UV Warn flags are set in the respective register, and the SMBA signal is asserted. VIN_OV_WARN_LIMIT (57h) The VIN_OV_WARN_LIMIT command is a standard PMBus command that allows configuring or reading the threshold for the VIN over-voltage warning detection. Reading and writing to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read or write word protocol. If the measured value of VIN rises above the value in this register, VIN OV Warn flags are set in the respective registers and the SMBA signal is asserted. TABLE 8. VIN_UV_WARN_LIMIT Register Value Meaning 1h – 0FFFh VIN Under-voltage 0000h (disabled) Warning detection threshold 0000h VIN Under-voltage n/a Warning disabled TABLE 7. VIN_OV_WARN_LIMIT Register Value Meaning 0h – 0FFEh VIN Over-voltage 0FFFh (disabled) Warning detection threshold Default 0FFFh VIN Over-voltage Warning disabled Default STATUS_BYTE (78h) The STATUS BYTE is a standard PMBus command that returns the value of a number of flags indicating the state of the LM5066. Accesses to this command should use the PMBus read byte protocol. To clear bits in this register, the underlying fault should be removed on the system and a CLEAR_FAULTS command issued. n/a VIN_UV_WARN_LIMIT (58h) The VIN_UV_WARN_LIMIT command is a standard PMBus command that allows configuring or reading the threshold for the VIN under-voltage warning detection. Reading and writing TABLE 9. STATUS_BYTE Definitions Bit NAME Meaning Default 7 BUSY Not Supported, always 0 0 6 OFF This bit is asserted if the MOSFET is not switched on for any reason. 1 5 VOUT OV Not Supported, always 0 0 4 IOUT OC Not Supported, always 0 0 3 VIN UV Fault A VIN Under-voltage Fault has occurred 1 2 TEMPERATURE A Temperature Fault or Warning has occurred 0 1 CML A Communication Fault has occurred 0 0 None of the Above A fault or warning not listed in bits [7:1] has occurred 1 the underlying fault should be removed and a CLEAR _FAULTS command issued. The INPUT and VIN UV flags will default to 1 on startup, however, they will be cleared to 0 after the first time the input voltage exceeds the resistor-programmed UVLO threshold. STATUS_WORD (79h) The STATUS_WORD command is a standard PMBus command that returns the value of a number of flags indicating the state of the LM5066. Accesses to this command should use the PMBus read word protocol. To clear bits in this register, TABLE 10. STATUS_WORD Definitions Bit NAME Meaning Default 15 VOUT An output voltage fault or warning has occurred 0 14 IOUT/POUT Not Supported, always 0 0 13 INPUT An input voltage or current fault has occurred 1 12 MFR A Manufacturer Specific Fault or Warning has occurred 1 11 POWER GOOD The Power Good signal has been negated 1 10 FANS Not Supported, always 0 0 9 OTHER Not Supported, always 0 0 8 UNKNOWN Not Supported, always 0 0 7 BUSY Not Supported, always 0 0 6 OFF This bit is asserted if the MOSFET is not switched on for any reason. 1 5 VOUT OV Not Supported, always 0 0 4 IOUT OC Not Supported, always 0 0 www.national.com 30 NAME Meaning Default 3 VIN UV A VIN Under-voltage Fault has occurred 1 2 TEMPERATURE A Temperature Fault or Warning has occurred 0 1 CML A Communication Fault has occurred 0 0 None of the Above A fault or warning not listed in bits [7:1] has occurred 1 Accesses to this command should use the PMBus read byte protocol. To clear bits in this register, the underlying fault should be cleared and a CLEAR_FAULTS command issued. STATUS_VOUT (7Ah) The STATUS_VOUT command is a standard PMBus command that returns the value of the VOUT UV Warn flag. TABLE 11. STATUS_VOUT Definitions Bit NAME Meaning Default 7 VOUT OV Fault Not Supported, always 0 0 6 VOUT OV Warn Not Supported, always 0 0 5 VOUT UV Warn A VOUT Under-voltage Warning has occurred 0 4 VOUT UV Fault Not Supported, always 0 0 3 VOUT Max Not Supported, always 0 0 2 TON Max Fault Not Supported, always 0 0 1 TOFF Max Fault Not Supported, always 0 0 0 VOUT Tracking Error Not Supported, always 0 0 register, the underlying fault should be cleared and a CLEAR_FAULTS command issued. The VIN UV Warn flag will default to 1 on startup, however, it will be cleared to 0 after the first time the input voltage increases above the resistorprogrammed UVLO threshold. STATUS_INPUT (7Ch) The STATUS_INPUT command is a standard PMBus command that returns the value of a number of flags related to input voltage, current, and power. Accesses to this command should use the PMBus read byte protocol. To clear bits in this TABLE 12. STATUS_INPUT Definitions Bit NAME Meaning Default 7 VIN OV Fault A VIN Over-voltage Fault has occurred 0 6 VIN OV Warn A VIN Over-voltage Warning has occurred 0 5 VIN UV Warn A VIN Under-voltage Warning has occurred 1 4 VIN UV Fault A VIN Under-voltage Fault has occurred 0 3 Insufficient Voltage Not Supported, always 0 0 2 IIN OC Fault An IIN Over-current Fault has occurred 0 1 IIN OC Warn An IIN Over-current Warning has occurred 0 0 PIN OP Warn A PIN Over-power Warning has occurred 0 mand should use the PMBus read byte protocol. To clear bits in this register, the underlying fault should be cleared and a CLEAR_FAULTS command issued. STATUS_TEMPERATURE (7dh) The STATUS_TEMPERATURE is a standard PMBus command that returns the value of the of a number of flags related to the temperature telemetry value. Accesses to this com- TABLE 13. STATUS_TEMPERATURE Definitions Bit NAME Meaning Default 7 Overtemp Fault An Overtemperature Fault has occurred 0 6 Overtemp Warn An Overtemperature Warning has occurred 0 5 Undertemp Warn Not Supported, always 0 0 4 Undertemp Fault Not Supported, always 0 0 3 reserved Not Supported, always 0 0 2 reserved Not Supported, always 0 0 1 reserved Not Supported, always 0 0 0 reserved Not Supported, always 0 0 31 www.national.com LM5066 Bit LM5066 faults. Accesses to this command should use the PMBus read byte protocol. To clear bits in this register, a CLEAR_FAULTS command should be issued. STATUS_CML (7Eh) The STATUS_CML is a standard PMBus command that returns the value of a number of flags related to communication TABLE 14. STATUS_CML Definitions Bit NAME Default 7 Invalid or unsupported command received 0 6 Invalid or unsupported data received 0 5 Packet Error Check failed 0 4 Not supported, always 0 0 3 Not supported, always 0 0 2 Not supported, always 0 0 1 Miscellaneous communications fault has occurred 0 0 Not supported, always 0 0 TABLE 17. READ_VOUT Register STATUS_MFR_SPECIFIC (80h) The STATUS_MFR_SPECIFIC command is a standard PMBus command that contains manufacturer specific status information. Accesses to this command should use the PMBus read byte protocol. To clear bits in this register, the underlying fault should be removed and a CLEAR_FAULTS command should be issued. Meaning Default 7 Circuit breaker fault 0 6 Ext. MOSFET shorted fault 0 5 Not Supported, Always 0 0 4 Defaults loaded 1 3 Not supported: Always 0 0 2 Not supported: Always 0 0 1 Not supported: Always 0 0 0 Not supported: Always 0 0 Meaning Default 0h – 0FFFh Measured value for VOUT 0000h READ_TEMPERATURE_1 (8Dh) The READ_TEMPERATURE_1 command is a standard PMBus command that returns the signed value of the temperature measured by the external temperature sense diode. Reading this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read word protocol. This value is also used internally for the Over Temperature Fault and Warning detection. This data has a range of -256°C to + 255°C after the coefficients are applied. TABLE 15. STATUS_MFR_SPECIFIC Definitions Bit Value TABLE 18. READ_TEMPERATURE_1 Register READ_VIN (88h) The READ_VIN command is a standard PMBus command that returns the 12-bit measured value of the input voltage. Reading this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read word protocol. This value is also used internally for the VIN Over and Under Voltage Warning detection. Value Meaning Default 0h – 0FFFh Measured value for TEMPERATURE 0000h MFR_ID (99h) The MFR_ID command is a standard PMBus command that returns the identification of the manufacturer. To read the MFR_ID, use the PMBus block read protocol. TABLE 19. MFR_ID Register TABLE 16. READ_VIN Register Byte Name 0 Number of bytes Value 03h 4Eh ‘N’ Value Meaning Default 1 MFR ID-1 0h – 0FFFh Measured value for VIN 0000h 2 MFR ID-2 53h ‘S’ 3 MFR ID-3 43h ‘C’ READ_VOUT (8Bh) The READ_VOUT command is a standard PMBus command that returns the 12-bit measured value of the output voltage. Reading this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Accesses to this command should use the PMBus read word protocol. This value is also used internally for the VOUT Under Voltage Warning detection. www.national.com MFR_MODEL (9Ah) The MFR_MODEL command is a standard PMBus command that returns the part number of the chip. To read the MFR_MODEL, use the PMBus block read protocol. 32 Name 0 Number of bytes 08h 1 MFR ID-1 4Ch ‘L’ 2 MFR ID-2 4Dh ‘M’ 3 MFR ID-3 35h ‘5’ 4 MFR ID-4 30h ‘0’ 5 MFR ID-5 36h ‘6’ 6 MFR ID-6 36h ‘6’ 7 MFR ID-7 00h 8 Manufacturer Specific PMBus™ Commands Value MFR ID-8 MFR_SPECIFIC_00: READ_VAUX (D0h) The READ_VAUX command will report the 12-bit ADC measured auxiliary voltage. Voltages greater than or equal to 2.97V to ground will be reported at plus full scale (0FFFh). Voltages less than or equal to 0V referenced to ground will be reported as 0 (0000h). To read data from the READ_VAUX command, use the PMBus Read Word protocol. TABLE 22. READ_VAUX Register 00h MFR_REVISION (9Bh) The MFR_REVISION command is a standard PMBus command that returns the revision level of the part. To read the MFR_REVISION, use the PMBus block read protocol. Name Value 0 Number of bytes 02h 1 MFR ID-1 41h ‘A’ 2 MFR ID-2 41h ‘A’ Meaning Default 0h – 0FFFh Measured value for VAUX input 0000h MFR_SPECIFIC_01: MFR_READ_IIN (D1h) The MFR_READ_IIN command will report the 12-bit ADC measured current sense voltage. To read data from the MFR_READ_IIN command, use the PMBus Read Word protocol. Reading this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Please see the section on coefficient calculations to calculate the values to use. TABLE 21. MFR_REVISION Register Byte Value TABLE 23. MFR_READ_IIN Register Value Meaning Default 0h – 0FFFh Measured value for input current sense voltage 0000h MFR_SPECIFIC_02: MFR_READ_PIN (D2h) The MFR_READ_PIN command will report the upper 12 bits of the VIN x IIN product as measured by the 12-bit ADC. To read data from the MFR_READ_PIN command, use the PMBus Read Word protocol. Reading this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Please see the section on coefficient calculations to calculate the values to use. TABLE 24. MFR_READ_PIN Register Value Meaning Default 0h – 0FFFh Value for input current x input voltage 0000h MFR_SPECIFIC_03: MFR_IN_OC_WARN_LIMIT (D3h) The MFR_IIN_OC_WARN_LIMIT PMBus command sets the input over-current warning threshold. In the event that the input current rises above the value set in this register, the IIN Over-current flags are set in the respective registers and the SMBA is asserted. To access the MFR_IIN_OC_WARN_LIMIT register, use the PMBus Read/Write Word protocol. Reading/writing to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. 33 www.national.com LM5066 TABLE 20. MFR_MODEL Register Byte LM5066 TABLE 25. MFR_IIN_OC_WARN_LIMIT Register Value Meaning Default 0h – 0FFEh Value for input over-current warn limit 0FFFh 0FFFh Input over-current n/a warning disabled MFR_SPECIFIC_07: GATE_MASK (D7h) The GATE_MASK register allows the hardware to prevent fault conditions from switching off the MOSFET. When the bit is high, the corresponding FAULT has no control over the MOSFET gate. All status registers will still be updated (STATUS, DIAGNOSTIC) and an SMBA will still be asserted. This register is accessed with the PMBus Read / Write Byte protocol. Warning: Inhibiting the MOSFET switch off in response to over-current or circuit breaker fault conditions will likely result in the destruction of the MOSFET! This functionality should be used with great care and supervision! MFR_SPECIFIC_04: MFR_PIN_OP_WARN_LIMIT (D4h) The MFR_PIN_OP_WARN_LIMIT PMBus command sets the input over-power warning threshold. In the event that the input power rises above the value set in this register, the PIN Overpower flags are set in the respective registers and the SMBA is asserted. To access the MFR_PIN_OP_WARN_LIMIT register, use the PMBus Read/Write Word protocol. Reading/ writing to this register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. TABLE 28. MFR_SPECIFIC_07 GATE MASK Definitions TABLE 26. MFR_PIN_OPWARN_LIMIT Register Bit NAME Default 7 Not used, always 0 0 6 Not used, always 0 0 5 VIN UV FAULT 0 4 VIN OV FAULT 0 Value Meaning Default 3 IIN/PFET FAULT 0 0h – 0FFEh Value for input over power warn limit 0FFFh 2 OVERTEMP FAULT 0 1 Not used, always 0 0 0 0 Input over power warning disabled n/a CIRCUIT BREAKER FAULT 0FFFh The IIN/PFET Fault refers to the input current fault and the MOSFET power dissipation fault. There is no input power fault detection; only input power warning detection. MFR_SPECIFIC_05: READ_PIN_PEAK (D5h) The READ_PIN_PEAK command will report the maximum input power measured since a Power On reset or the last CLEAR_PIN_PEAK command. To access the READ_PIN_PEAK command, use the PMBus Read Word protocol. Use the coefficients shown in the Telemetry and Warning Coefficients Table. MFR_SPECIFIC_08: ALERT_MASK (D8h) The ALERT_MASK command is used to mask the SMBA when a specific fault or warning has occurred. Each bit corresponds to one of the 14 different analog and digital faults or warnings that would normally result in an SMBA being asserted. When the corresponding bit is high, that condition will not cause the SMBA to be asserted. If that condition occurs, the registers where that condition is captured will still be updated (STATUS registers, DIAGNOSTIC_WORD) and the external MOSFET gate control will still be active (VIN_OV_FAULT, VIN_UV_FAULT, IIN/PFET_FAULT, CB_FAULT, OT_FAULT). This register is accessed with the PMBus Read / Write Word protocol. The VIN UNDERVOLTAGE FAULT flag will default to 1 on startup, however, it will be cleared to 0 after the first time the input voltage increases above the resistor-programmed UVLO threshold. TABLE 27. READ_PIN_PEAK Register Value Meaning 0h – 0FFEh Maximum Value 0h for input current x input voltage since reset or last clear Default MFR_SPECIFIC_06: CLEAR_PIN_PEAK (D6h) The CLEAR_PIN_PEAK command will clear the PIN PEAK register. This command uses the PMBus Send Byte protocol. TABLE 29. ALERT_MASK Definitions www.national.com BIT NAME DEFAULT 15 VOUT UNDERVOLTAGE WARN 0 14 IIN LIMIT Warn 0 13 VIN UNDERVOLTAGE WARN 0 12 VIN OVERVOLTAGE WARN 0 11 POWER GOOD 1 10 OVERTEMP WARN 0 9 Not Used 0 8 OVERPOWER LIMIT WARN 0 7 Not Used 0 6 EXT_MOSFET_SHORTED 0 34 NAME DEFAULT 5 VIN UNDERVOLTAGE FAULT 1 4 VIN OVERVOLTAGE FAULT 0 3 IIN/PFET FAULT 0 2 OVERTEMPERATURE FAULT 0 1 CML FAULT (Communications Fault) 0 0 CIRCUIT BREAKER FAULT 0 LM5066 BIT terface is idle. BLOCK_READ also guarantees that the VIN, VOUT, IIN and PIN measurements are all time-aligned. If separate commands are used, individual samples may not be time-aligned, because of the delay necessary for the communication protocol. The Block Read command is read via the PMBus block read protocol. MFR_SPECIFIC_09: DEVICE_SETUP (D9h) The DEVICE_SETUP command may be used to override pin settings to define operation of the LM5066 under host control. This command is accessed with the PMBus read / write byte protocol. TABLE 30. DEVICE_SETUP Byte Format Bit 7:5 Name Retry setting TABLE 31. BLOCK_READ Register Format Meaning 111 = Unlimited retries 110 = Retry 16 times 101 = Retry 8 times 100 = Retry 4 times 011 = Retry 2 times 010 = Retry 1 time 001 = No retries Byte Count (always 12) (1 byte) DIAGNOSTIC_WORD (1 Word) IIN_BLOCK (1 Word) VOUT_BLOCK (1 Word) VIN_BLOCK (1 Word) PIN_BLOCK (1 Word) TEMP_BLOCK (1 Word) 000 = Pin configured retries 4 Current limit setting 3 CB/CL Ratio 2 Current Limit Configuration MFR_SPECIFIC_11: SAMPLES_FOR_AVG (DBh) The SAMPLES_FOR_AVG command is a manufacturer specific command for setting the number of samples used in computing the average values for IIN, VIN, VOUT, PIN. The decimal equivalent of the AVGN nibble is the power of 2 samples, (e.g. AVGN=12 equates to N=4096 samples used in computing the average). The LM5066 supports average numbers of 1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 4096. The SAMPLES_FOR_AVG number applies to average values of IIN, VIN, VOUT, PIN simultaneously. The LM5066 uses simple averaging. This is accomplished by summing consecutive results up to the number programmed, then dividing by the number of samples. Averaging is calculated according to the following sequence: 0 = High setting (50mV) 1 = Low setting (26mV) 0 = Low setting (1.9x) 1 = High setting (3.9x) 1 Unused 0 Unused 0 = Use pin settings 1 = Use SMBus settings In order to configure the Current Limit Setting via this register, it is necessary to set the Current Limit Configuration bit (2) to 1 to enable the register to control the current limit function and the Current Limit Setting bit (4) to select the desired setting. If the Current Limit Configuration bit is not set, the pin setting will be used. The Circuit Breaker to Current Limit ratio value is set by the CB / CL Ratio bit (3). Note that if the Current Limit Configuration is changed, the samples for the telemetry averaging function will not be reset. It is recommeded to allow a full averaging update period with the new Current Limit Configuration before processing the averaged data. Note that the Current Limit Configuration affects the coefficients used for the Current and Power measurements and warning registers. Y = (X(N) + X(N-1) + ... + X(0)) / N When the averaging has reached the end of a sequence (for example, 4096 samples are averaged), then a whole new sequence begins that will require the same number of samples (in this example, 4096) to be taken before the new average is ready. TABLE 32. SAMPLES_FOR_AVG Register MFR_SPECIFIC_10: BLOCK_READ (DAh) The BLOCK_READ command concatenates the DIAGNOSTIC_WORD with input and output telemetry information (IIN, VOUT, VIN, PIN) as well as TEMPERATURE to capture all of the operating information of the LM5066 in a single SMBus transaction. The block is 12 bytes long with telemetry information being sent out in the same manner as if an individual READ_XXX command had been issued (shown below). The contents of the block read register are updated every clock cycle (85ns) as long as the SMBus in- 35 AVGN N = 2AVGN Averaging/Register Update Period (ms) 0000 1 1 0001 2 2 0010 4 4 0011 8 8 0100 16 16 0101 32 32 0110 64 64 0111 128 128 1000 256 256 www.national.com LM5066 AVGN N = 2AVGN Averaging/Register Update Period (ms) 1001 512 512 1010 1024 1024 1011 2048 2048 1100 4096 4096 MFR_SPECIFIC_14: READ_AVG_IIN (DEh) The READ_AVG_IIN command will report the 12-bit ADC measured current sense average voltage. The returned value will be the default value (0000h) or previous data when the average data is not ready. This data is read with the PMBus Read Word protocol. This register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Note that a change in the SAMPLES_FOR_AVG register will not be reflected in the average telemetry measurements until the present averaging interval has completed. The default setting for AVGN is 0000, therefore, the average telemetry will mirror the instantaneous telemetry until a value higher than zero is programmed. The SAMPLES_FOR_AVG register is accessed via the PMBus read / write byte protocol. TABLE 36. READ_AVG_IIN Register Value Meaning Default 0h – 0FFFh Average of measured values for current sense voltage 0000h TABLE 33. SAMPLES_FOR_AVG Register Value Meaning Default 0h – 0Ch Exponent (AVGN) 00h for number of samples to average over MFR_SPECIFIC_15: READ_AVG_PIN The READ_AVG_PIN command will report the upper 12-bits of the average VIN x IIN product as measured by the 12-bit ADC. You will read the default value (0000h) or previous data when the average data is not ready. This data is read with the PMBus Read Word protocol. This register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. MFR_SPECIFIC_12: READ_AVG_VIN (DCh) The READ_AVG_VIN command will report the 12-bit ADC measured input average voltage. If the data is not ready, the returned value will be the previous averaged data. However, if there is no previously averaged data, the default value (0000h) will be returned. This data is read with the PMBus Read Word protocol. This register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. TABLE 37. READ_AVG_PIN Register TABLE 34. READ_AVG_VIN Register Value Meaning Default 0h – 0FFFh Average of measured values for input voltage 0000h TABLE 35. READ_AVG_VOUT Register Meaning Default 0h – 0FFFh Average of measured values for output voltage 0000h www.national.com Meaning 0h – 0FFFh Average of 0000h measured value for input voltage x input current sense voltage Default MFR_SPECIFIC_16: BLACK_BOX_READ (E0h) The BLACK BOX READ command retrieves the BLOCK READ data which was latched in at the first assertion of SMBA by the LM5066. It is re-armed with the CLEAR_FAULTS command. It is the same format as the BLOCK_READ registers, the only difference being that its contents are updated with the SMBA edge rather than the internal clock edge. This command is read with the PMBus Block Read protocol. MFR_SPECIFIC_13: READ_AVG_VOUT (DDh) The READ_AVG_VOUT command will report the 12-bit ADC measured current sense average voltage. The returned value will be the default value (0000h) or previous data when the average data is not ready. This data is read with the PMBus Read Word protocol. This register should use the coefficients shown in the Telemetry and Warning Conversion Coefficients Table. Value Value 36 TABLE 38. DIAGNOSTIC_WORD Format Bit Meaning Default 15 VOUT_UNDERVOLTAGE_WARN 0 14 IIN_OP_WARN 0 13 VIN_UNDERVOLTAGE_WARN 0 12 VIN_OVERVOLTAGE_WARN 0 11 POWER GOOD 1 10 OVER_TEMPERATURE_WARN 0 9 TIMER_LATCHED_OFF 0 8 EXT_MOSFET_SHORTED 0 7 CONFIG_PRESET 1 6 DEVICE_OFF 1 5 VIN_UNDERVOLTAGE_FAULT 1 4 VIN_OVERVOLTAGE_FAULT 0 3 IIN_OC/PFET_OP_FAULT 0 2 OVER_TEMPERATURE_FAULT 0 1 CML_FAULT 0 0 CIRCUIT_BREAKER_FAULT 0 TABLE 39. AVG_BLOCK_READ Register Format MFR_SPECIFIC_18: AVG_BLOCK_READ (E2h) The AVG_BLOCK_READ command concatenates the DIAGNOSTIC_WORD with input and output average telemetry information (IIN, VOUT, VIN, PIN) as well as temperature to capture all of the operating information of the part in a single PMBus transaction. The block is 12 bytes long with telemetry information being sent out in the same manner as if an individual READ_AVG_XXX command had been issued (shown below). AVG_BLOCK_READ also guarantees that the VIN, VOUT, and IIN measurements are all time-aligned whereas there is a chance they may not be if read with individual PMBus commands. To read data from the AVG_BLOCK_READ command, use the SMBus Block Read protocol. 37 Byte Count (always 12) (1 byte) DIAGNOSTIC_W ORD (1 word) AVG_IIN (1 word) AVG_VOUT (1 word) AVG_VIN (1 word) AVG_PIN (1 word) TEMPERATURE (1 word) www.national.com LM5066 DIAGNOSTIC_WORD register. The READ_DIAGNOSTIC_WORD command should be read with the PMBus Read Word protocol. The READ_DIAGNOSTIC_WORD is also returned in the BLOCK_READ, BLACK_BOX_READ, and AVG_BLOCK_READ operations. MFR_SPECIFIC_17: READ_DIAGNOSTIC_WORD (E1h) The READ_DIAGNOSTIC_WORD PMBus command will report all of the LM5066 faults and warnings in a single read operation. The standard response to the assertion of the SMBA signal of issuing multiple read requests to various status registers can be replaced by a single word read to the LM5066 301159a2 FIGURE 18. Command/Register and Alert Flow Diagram www.national.com 38 All measured telemetry data and user programmed warning thresholds are communicated in 12-bit two’s compliment binary numbers read/written in 2 byte increments conforming to the Direct format as described in section 8.3.3 of the PMBus Power System Management Protocol Specification 1.1 (Part TABLE 40. Telemetry and Warning Word Format Byte B7 B6 B5 B4 B3 B2 B1 B0 1 Bit_7 Bit_6 Bit_5 Bit_4 Bit_3 Bit_2 Bit_1 Bit_0 2 0 0 0 0 Bit_11 Bit_10 Bit_9 Bit_8 Conversion from direct format to real-world dimensions of current, voltage, power, and temperature is accomplished by determining appropriate coefficients as described in section 7.2.1 of the PMBus Power System Management Protocol Specification 1.1 (Part II). According to this specification, the host system converts the values received into a reading of volts, amperes, watts, or other units using the following relationship: Where: X: the calculated "real-world" value (volts, amps, watt, etc.) m: the slope coefficient Y: a two byte two's complement integer received from device b: the offset, a two byte, two's complement integer R: the exponent, a one byte two's complement integer R is only necessary in systems where m is required to be an integer (for example, where m may be stored in a register in an integrated circuit). In those cases, R only needs to be large enough to yield the desired accuracy. TABLE 41. Telemetry and Warning Conversion Coefficients Commands Condition Format Number of Data Bytes m b R Units READ_VIN, READ_AVG_VIN VIN_OV_WARN_LIMIT VIN_UV_WARN_LIMIT DIRECT 2 4587 -1200 -2 V READ_VOUT, READ_AVG_VOUT VOUT_UV_WARN_LIMIT DIRECT 2 4587 -2400 -2 V DIRECT 2 13793 0 -1 V *READ_IIN, READ_AVG_IIN MFR_IIN_OC_WARN_LIMIT READ_VAUX CL = VDD DIRECT 2 10753 -1200 -2 A *READ_IN, READ_AVG_IN MFR_IIN_OC_WARN_LIMIT CL = GND DIRECT 2 5405 -600 -2 A *READ_PIN, READ_AVG_PIN, READ_PIN_PEAK MFR_PIN_OP_WARN_LIMIT CL = VDD DIRECT 2 1204 -6000 -3 W *READ_PIN, READ_AVG_PIN, READ_PIN_PEAK MFR_PIN_OP_WARN_LIMIT CL = GND DIRECT 2 605 -8000 -3 W DIRECT 2 16000 0 -3 °C READ_TEMPERATURE_1 OT_WARN_LIMIT OT_FAULT_LIMIT * The coefficients relating to current/power measurements and warning thresholds shown in Table 41 are normalized to a sense resistor (RS) value of 1mΩ. In general, the current/power coefficients can be calculated using the relationships shown in Table 42. 39 www.national.com LM5066 II). The organization of the bits in the telemetry or warning word is shown in Table 40, where Bit_11 is the most significant bit (MSB) and Bit_0 is the least significant bit (LSB). The decimal equivalent of all warning and telemetry words are constrained to be within the range of 0 to 4095, with the exception of temperature. The decimal equivalent value of the temperature word ranges from 0 to 65535. Reading and Writing Telemetry Data and Warning Thresholds LM5066 TABLE 42. Current and Power Telemetry and Warning Conversion Coefficients (RS in mΩ) Commands Condition Format Number of Data Bytes m b R Units *READ_IIN, READ_AVG_IIN MFR_IIN_OC_WARN_LIMIT CL = VDD DIRECT 2 10753 x RS -1200 -2 A *READ_IIN, READ_AVG_IIN MFR_IIN_OC_WARN_LIMIT CL = GND DIRECT 2 5405 x RS -600 -2 A *READ_PIN, READ_AVG_PIN, READ_PIN_PEAK MFR_PIN_OP_WARN_LIMIT CL = VDD DIRECT 2 1204 x RS -6000 -3 W *READ_PIN, READ_AVG_PIN, READ_PIN_PEAK MFR_PIN_OP_WARN_LIMIT CL = GND DIRECT 2 605 x RS -8000 -3 W Care must be taken to adjust the exponent coefficient, R, such that the value of m remains within the range of -32768 to +32767. For example, if a 5 mΩ sense resistor is used, the correct coefficients for the READ_IIN command with CL = VDD would be m = 5359, b = -120, R = -1. A Note on the "b" Coefficient Since b coefficients represent offset, for simplification b is set to zero in the following discussions. efficients enable the data output to be converted to amps. The values shown in the example are based on having the device programmed for a 26 mV current limit threshold (CL = VDD). In the 26mV range, the LSB value is 9.3 µV and the full scale range is 38.0 mV. In the 50mV range (CL = GND), the LSB value is 18.5 µV and the full scale range in 76.0 mV. Reading Current The current register actually displays a value equivalent to a voltage across the user specified sense resistor, RS. The coStep 1. Determine full scale current and shunt value based on 38.0 mV across shunt at full scale: Example Example: 8.6A application with 3 mΩ shunt. or: 2. Determine m': 3. Determine exponent R necessary to set m' to integer value m: Select R to provide 16 bit accuracy for the integer value of m: R = -1 4. Final values m = 3233 R = -1 b=0 www.national.com 40 Coefficients for VIN and VOUT are fixed and are consistent between read telemetry measurements (e.g., READ_VIN, READ_AVG_VIN) and warning thresholds (e.g., Step Example 1. Determine m' based on full scale analog input and full scale digital range: 2. Determine exponent R necessary to set m' to integer value m Select R to provide 16 bit accuracy for the integer value of m: with desired accuracy: (4585 in this example): R = -2 3. Final values m = 4586 R = -2 b =0 For this reason power coefficients will also vary depending on the shunt value and must be calculated for each application. The power LSB will vary depending on shunt value according to 828 µW/Rsense for the 26mV range or 1.65 mW/Rsense for the 50mV range. Reading Power The power calculation of the LM5066 is a relative power calculation meaning that full scale of the power register corresponds to simultaneous full scale values in the current register and voltage register such that the power register has the following relationship based on decimal equivalents of the register contents: Step Example 1. Determine full scale power from known full scale of input current and input voltage: PIN_MAX = VIN_MAX x IIN_MAX Example: 8.6A application with 3 mΩ shunt. PIN_MAX = (89.3V) x (76 mV / 3 mΩ) = 2262W 2. Determine m': 3. Optional: Determine exponent R necessary to set m' to integer Select R to provide 16 bit accuracy for the integer value of m : value m with desired accuracy: R = -4 4. Final values m = 18103 R = -4 b=0 41 www.national.com LM5066 VIN_UV_WARN_LIMIT). Input and output voltage values are read/written in Direct format with 12-bit resolution and a 21.8 mV LSB. An example of calculating the PMBus coefficients for input voltage is shown below. Reading Input and Output Voltage LM5066 4. Determining Telemetry Coefficients Empirically with Linear Fit The coefficients for telemetry measurements and warning thresholds presented in Table 41 are adequate for the majority of applications. Current and power coefficients must be calculated per application as they are dependent on the value of the sense resistor, RS, used. Table 42 provides the equations necessary for calculating the current and power coefficients for the general case. The small signal nature of the current measurement make it and the power measurement more susceptible to PCB parasitics than other telemetry channels. This may cause slight variations in the optimum coefficients (m, b, R) for converting from Direct format digital values to real-world values (e.g., Amps and Watts). The optimum coefficients can be determined empirically for a specific application and PCB layout using two or more measurements of the telemetry channel of interest. The current coefficients can be determined using the following method: 1. While the LM5066 is in normal operation measure the voltage across the sense resistor using kelvin test points and a high accuracy DVM while controlling the load current. Record the integer value returned by the READ_AVG_IIN command (with the SAMPLES_FOR_AVG set to a value greater than 0) for two or more voltages across the sense resistor. For best results, the individual READ_AVG_IIN measurements should span nearly the full scale range of the current (For example, voltage across RS of 5mV and 20mV). 2. Convert the measured voltages to currents by dividing them by the value of RS. For best accuracy the value of RS should be measured. Table 43 assumes a sense resistor value of 5mΩ. 5. Where: X: the calculated "real-world" value (volts, amps, watts, temperature) m: the slope coefficient, is the two byte, two's complement integer Y: a two byte two's complement integer received from device b: the offset, a two byte, two's complement integer R: the exponent, a one byte two's complement integer The above procedure can be repeated to determine the coefficients of any telemetry channel simply by substituting measured current for some other parameter (e.g., power, voltage, etc.). Writing Telemetry Data TABLE 43. Measurements for linear fit determination of current coefficients: Measured voltage Measured Current across (A) RS (V) 3. There are several locations that will require writing data if their optional usage is desired. Use the same coefficients previously calculated for your application, and apply them using this method as prescribed by the PMBus revision section 7.2.2 "Sending a Value" READ_AVG_IIN (integer value) 0.005 1 568 0.01 2 1108 0.02 4 2185 Y = (mX + b) x 10R Where: X: the calculated "real-world" value (volts, amps, watts, temperature) m: the slope coefficient, is the two byte, two's complement integer Y: a two byte two's complement integer received from device b: the offset, a two byte, two's complement integer R: the exponent, a one byte two's complement integer Using the spreadsheet or math program of your choice determine the slope and the y-intercept of the data returned by the READ_AVG_IIN command versus the measured current. For the data shown in Table 42: READ_AVG_IN value = slope x (Measured Current) + (yintercept) slope = 538.9 y-intercept = 29.5 www.national.com To determine the ‘m’ coefficient, simply shift the decimal point of the calculated slope to arrive at at integer with a suitable number of significant digits for accuracy (typically 4) while staying with the range of -32768 to +32767. This shift in the decimal point equates to the ‘R’ coefficient. For the slope value shown above, the decimal point would be shifted to the right once hence R = -1. Once the ‘R’ coefficient has been determined, the ‘b’ coefficient is found by multiplying the y-intercept by 10-R. In this case the value of b = 295. Calculated Current Coefficients: m = 5389 b = 295 R = -1 42 The three address lines are to be set high (connect to VDD), low (connect to GND), or open to select one of 27 addresses TABLE 44. Device Addressing ADR2 ADR1 ADR0 Decoded Address Z Z Z 40h Z Z 0 41h Z Z 1 42h Z 0 Z 43h Z 0 0 44h Z 0 1 45h Z 1 Z 46h Z 1 0 47h Z 1 1 10h 0 Z Z 11h 0 Z 0 12h 0 Z 1 13h 0 0 Z 14h 0 0 0 15h 0 0 1 16h 0 1 Z 17h 0 1 0 50h 0 1 1 51h 1 Z Z 52h 1 Z 0 53h 1 Z 1 54h 1 0 Z 55h 1 0 0 56h 1 0 1 57h 1 1 Z 58h 1 1 0 59h 1 1 1 5Ah 43 www.national.com LM5066 for communicating with the LM5066. Table 44 depicts 7-bit addresses (eighth bit is read/write bit): PMBus™ Address Lines (ADR0, ADR1, ADR2) LM5066 SMBus Communications Timing Requirements 301159a1 FIGURE 19. SMBus Timing Diagram TABLE 45. SMBus Timing Definition Symbol Limits Parameter Min Max 400 Units FSMB SMBus Operating Frequency 10 TBUF Bus free time between Stop and Start Condition 1.3 µs THD:STA Hold time after (Repeated) Start Condition. After this period, the first clock is generated. 0.6 µs TSU:STA Repeated Start Condition setup time 0.6 µs TSU:STO Stop Condition setup time 0.6 µs THD:DAT Data hold time 85 ns TSU:DAT Data setup time 100 TTIMEOUT Clock low time-out 25 Comments kHz ns 35 ms (Note 8) TLOW Clock low period 1.5 µs THIGH Clock high period 0.6 µs (Note 9) TLOW:SEXT Cumulative clock low extend time (slave device) 25 ms (Note 10) TLOW:MEXT Cumulative low extend time (master device) 10 ms (Note 11) TF Clock or Data Fall Time 20 300 ns (Note 12) TR Clock or Data Rise Time 20 300 ns (Note 12) Note 8: Devices participating in a transfer will timeout when any clock low exceeds the value of TTIMEOUT,MIN of 25 ms. Devices that have detected a timeout condition must reset the communication no later than TTIMEOUT,MAX of 35 ms. The maximum value must be adhered to by both a master and a slave as it incorporates the cumulative stretch limit for both a master (10ms) and a slave (25ms). Note 9: THIGH MAX provides a simple method for devices to detect bus idle conditions. Note 10: TLOW:SEXT is the cumulative time a slave device is allowed to extend the clock cycles in one message from the initial start to the stop. If a slave exceeds this time, it is expected to release both its clock and data lines and reset itself. Note 11: TLOW:MEXT is the cumulative time a master device is allowed to extend its clock cycles within each byte of a message as defined from start-to-ack, ackto-ack, or ack-to-stop. Note 12: Rise and fall time is defined as follows: • TR = ( VILMAX – 0.15) to (VIHMIN + 0.15) • TF = 0.9 VDD to (VILMAX – 0.15) www.national.com 44 The SMBA effectively has two masks: 1. The Alert Mask Register at D8h, and 2. The ARA Automatic Mask. The ARA Automatic Mask is a mask that is set in response to a successful ARA read. An ARA read operation returns the PMBus address of the lowest addressed part on the bus that has its SMBA asserted. A successful ARA read means that THIS part was the one that returned its address. When a part responds to the ARA read, it releases the SMBA signal. When 301159a0 FIGURE 20. Typical Flow Schematic for SMBA Fault 45 www.national.com LM5066 the last part on the bus that has an SMBA set has successfully reported its address, the SMBA signal will de-assert. The way that the LM5066 releases the SMBA signal is by setting the ARA Automatic mask bit for all fault conditions present at the time of the ARA read. All status registers will still show the fault condition, but it will not generate and SMBA on that fault again until the ARA Automatic mask is cleared by the host issuing a CLEAR_FAULTS command to this part. This should be done as a routine part of servicing an SMBA condition on a part, even if the ARA read is not done. Figure 20 depicts a schematic version of this flow. SMBA Response LM5066 Physical Dimensions inches (millimeters) unless otherwise noted NS Package Number MXA28A www.national.com 46 LM5066 Notes 47 www.national.com LM5066 High Voltage System Power Management and Protection IC with PMBus™ Notes For more National Semiconductor product information and proven design tools, visit the following Web sites at: www.national.com Products Design Support Amplifiers www.national.com/amplifiers WEBENCH® Tools www.national.com/webench Audio www.national.com/audio App Notes www.national.com/appnotes Clock and Timing www.national.com/timing Reference Designs www.national.com/refdesigns Data Converters www.national.com/adc Samples www.national.com/samples Interface www.national.com/interface Eval Boards www.national.com/evalboards LVDS www.national.com/lvds Packaging www.national.com/packaging Power Management www.national.com/power Green Compliance www.national.com/quality/green Switching Regulators www.national.com/switchers Distributors www.national.com/contacts LDOs www.national.com/ldo Quality and Reliability www.national.com/quality LED Lighting www.national.com/led Feedback/Support www.national.com/feedback Voltage References www.national.com/vref Design Made Easy www.national.com/easy www.national.com/powerwise Applications & Markets www.national.com/solutions Mil/Aero www.national.com/milaero PowerWise® Solutions Serial Digital Interface (SDI) www.national.com/sdi Temperature Sensors www.national.com/tempsensors SolarMagic™ www.national.com/solarmagic PLL/VCO www.national.com/wireless www.national.com/training PowerWise® Design University THE CONTENTS OF THIS DOCUMENT ARE PROVIDED IN CONNECTION WITH NATIONAL SEMICONDUCTOR CORPORATION (“NATIONAL”) PRODUCTS. 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