EM2130H01QI

Data SheeT Intel® Enpirion® Power Solutions EM2130x01QI 30A PowerSoC Step-Down DC-DC Switching Converter with Integrated Inductor, Featuring Digital Control with PMBusTM v1.2 Compliant Interface Description Features The EM2130 is a fully integrated 30A PowerSoC synchronous buck converter. It features an advanced digital controller, gate drivers, synchronous MOSFET switches, and a high performance inductor. Only input and output filter capacitors and a few small signal components are required for a complete solution. A PMBus version 1.2 compliant interface provides setup, control, and telemetry.      Differential remote sensing and ±0.5% set-point accuracy provide precise regulation over line, load and temperature variation. Very low ripple further reduces accuracy uncertainty to provide best in class static regulation for today’s FPGAs, ASICs, processors, and DDR memory devices.   The EM2130 may be used in standalone mode or utilizing the PMBus interface for a high degree of flexibility and programmability. Advanced digital control techniques ensure stability and excellent dynamic performance, and eliminate the need for external compensation components. The PC-based Intel Enpirion Digital Power Configurator provides a user-friendly and easy-to-use interface to the device for communication and configuration. The EM2130 features high conversion efficiency and superior thermal performance to minimize thermal de-rating limitations, which is key to product reliability and longevity.     Integrated inductor, FETs, and digital controller Wide 4.5V to 16V VIN range 0.7V to 3.6V VOUT range 30A continuous current with no thermal de-rating High efficiency in 11mm x 17mm x 6.76mm QFN package o 95% efficiency at VIN = 5V, VOUT = 3.3V o 90% efficiency at VIN = 12V, VOUT = 1.2V Optimized total solution size of only 365 mm2 Meets all high performance FPGA requirements o Digital loop for best in class transient response o 0.5% set-point over line, load, and temperature o Output ripple as low as 10 mV peak-peak o Differential remote sensing o Monotonic startup into pre-bias output o Optimized FPGA configs stored in NVM Programmable through PMBus o VOUT margining, startup and shutdown delays o Programmable warnings, faults and response Ability to operate without PMBus o RVSET resistor for programmable VOUT o RTUNE resistor for single resistor compensation Tracking pin for complex sequencing RoHS compliant, MSL level 3, 260C reflow Applications  High performance FPGA supply rails  ASIC and processor supply rails  High density double data rate (DDR) memory VDDQ rails Page 1 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Ordering Information Table 1 Part Number Supported VOUT Range Package Markings TAMBIENT Rating (°C) Package Description EM2130L01QI 0.7V to 1.325V M2130L -40 to +85 17 mm x 11 mm x 6.76 mm QFN100 provided in 112 units per tray EM2130H01QI 1.35V to 3.6V M2130H -40 to +85 17 mm x 11 mm x 6.76 mm QFN100 provided in 112 units per tray EVB-EM2130L01 0.7V to 1.325V Evaluation board; 30A single phase EVB-EM2130H01 1.35V to 3.6V Evaluation board; 30A single phase EVI-EM2COMIF GUI interface dongle Packing and Marking Information: www.altera.com/support/reliability/packing/rel-packing-andmarking.html Page 2 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Pin Assignments 91 82 VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT VOUT 100 PIN 1 VOUT VOUT VOUT RVSET RTUNE VINSEN ADDR1 ADDR0 PWM SYNC POK CTRL SALRT SDA SCL 16 VDD33 PVIN PVIN PVIN PVIN PVIN PGND PGND PGND PGND PGND PGND PGND PGND PGND 31 PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND VOUT 81 VOUT VOUT VCCSEN VTRACK NC NC NC NC VSENN VSENP AGND DGND NC NC VCC 66 PVCC PVIN PVIN PVIN PVIN PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND 51 32 41 100 82 101 VOUT 102 AGND 103 PVIN 104 PGND 50 32 50 Figure 1: Pin Out Diagram Page 3 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Pin Description Table 2 PIN NAME I/O FUNCTION 1,2,3, 79-101 VOUT Regulated Output Regulated output voltage. Decouple to PGND with appropriate filter capacitors 4 RVSET Analog I/O A resistor from RVSET to AGND; and can be used to program the V OUT set-point. Using 1% tolerance or better resistor. See Table 8 and Table 9 for more information. 5 RTUNE Analog I/O A resistor from RTUNE to AGND; and can be used to tune the transient compensator for the amount of output capacitance. Using 1% tolerance or better resistor. See Table 10 for more information. 6 VINSEN Analog Input Single-ended input voltage sense (relative to AGND). 7 ADDR1 Analog I/O A resistor from ADDR1 to AGND; and can be used to set the PMBus™ address. Use a 1% tolerance or better resistor. 8 ADDR0 Analog I/O A resistor from ADDR0 to AGND; and can be used to set the PMBus™ address. Use a 1% tolerance or better resistor. 9 PWM PWM PWM signal test pin. 10 SYNC Digital I/O PWM synchronization signal 11 POK Digital I/O Power OK signal. 12 CTRL Digital Input PMBus-compatible control pin with programmable functionality. CTRL should never be left floating if enabled in Configuration. The default configuration is for V OUT to be on with CTRL high (positive edge) 13 SALRT Digital Output PMBus™ alert line. 14 SDA Digital I/O PMBus™ serial data I/O. 15 SCL Digital Input PMBus™ serial clock input. 16 VDD33 Output 3.3V output of the internal LDO. May be used as pull-up supply for PMBus™ pins and CTRL pin. 17-21, 61-64, 103 PVIN Input Supply Input supply for MOSFET switches. Decouple to PGND with appropriate filter capacitors. Refer to Recommended Application Circuit section for more details. 22-60, 104 PGND Ground Power ground. Ground for MOSFET switches. 65 PVCC Input Supply 5.0V supply voltage for driver circuitry. Decouple to PGND using a 2.2µF MLCC high quality ceramic capacitor. 66 VCC Input Supply 5.0V supply voltage for analog circuitry. 67,68, 73-76 NC NC No connect. Do not connect to any signal, supply, or ground. 69 DGND Ground Digital ground. Connect to AGND pin directly. 70, 102 AGND Ground Analog ground. Connect to system ground plane. Refer to layout section for more details on grounding. Page 4 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 PIN NAME I/O FUNCTION 71 VSENP Analog Input Differential output voltage sense input (positive). 72 VSENN Analog Input Differential output voltage sense input (negative). 77 VTRACK Analog Input Voltage tracking reference input if EM2130 is configured for voltage tracking mode. May remain floating if not used. If enabled but not used, connect to VDD33 using a 10kΩ resistor. VTRACK is not enabled in the default configuration. 78 VCCSEN Analog Input Single-ended VCC voltage sense (relative to AGND) Page 5 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Absolute Maximum Ratings CAUTION: Absolute Maximum ratings are stress ratings only. Functional operation beyond the recommended operating conditions is not implied. Stress beyond the absolute maximum ratings may impair device life. Exposure to absolute maximum rated conditions for extended periods may affect device reliability. Voltage measurements are referenced to AGND. Absolute Maximum Pin Ratings Table 3 PARAMETER SYMBOL MIN MAX UNITS Supply voltage PVIN PVIN -0.3 18 V Supply voltage VCC VCC -0.3 5.5 V VCC ramp time VCC 20 ms VDD33 VDD33 -0.3 3.6 V Digital ground DGND -0.3 0.1 V Power ground PGND -0.3 0.3 V Digital I/O pins SALRT, POK, SYNC, -0.3 5.5 V Digital I/O pins SCL, SDA, CTRL -0.3 3.6 V Analog I/O pins VINSEN, VCCSEN, ADDR1, ADDR2, RVSET, RTUNE, VTRACK -0.3 2.0 V VSENP, VSENN -0.3 2.0 V PWM pin PWM -0.3 5.5 V Output voltage pins VOUT -0.3 3.8 V DC current on VOUT VOUT 35 A MAX UNITS +125 °C +150 °C +260 °C MAX UNITS Voltage feedback Absolute Maximum Thermal Ratings PARAMETER CONDITION MIN Operating junction temperature Storage temperature range -65 Reflow peak body temperature (10 Sec) MSL3 Absolute Maximum ESD Ratings PARAMETER HBD CONDITION MIN All pins; Except VINSEN 1000 V Max 2000 V 500 V CDM; all pins Page 6 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Recommended Operating Conditions Table 4 PARAMETER PINS MIN MAX UNITS PVIN supply voltage range PVIN 4.5 16 V Supply voltage VCC & PVCC VCC, PVCC 4.75 5.25 V 30 A Continuous load current VOUT Thermal Characteristics Table 5 PARAMETER PINS TYPICAL UNITS Thermal shutdown [programmable] TSD 120 °C Thermal shutdown Hysteresis TSDH 18 °C JA 8 JC 1.5 Thermal resistance: junction to ambient (0 LFM) (Note 1) Thermal resistance: junction to case bottom (0 LFM) °C/W °C/W Note 1: Based on 2 oz. external copper layers and proper thermal design in line with EIJ/JEDEC JESD51 standards for high thermal conductivity boards. No top side cooling required. Page 7 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Electrical Characteristics PVIN = 12V and VCC = 5.0V. The minimum and maximum values are over the operating ambient temperature range (-40°C to 85°C) unless otherwise noted. Typical values are at TA = 25°C. Table 6 PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNITS 16 V SUPPLY CHARACTERISTICS PVIN supply voltage range PVIN PVIN supply quiescent current VCC supply voltage range 4.5 Device switching; no load; fsw = 800 kHz; VOUT = 1.0V 40 Device not switching 1 VCC 4.75 5.0 mA 5.25 V VCC UVLO rising 4.4 V VCC UVLO falling 4.2 V Normal operation; no load; fsw = 800 kHz 80 mA Idle; communication and telemetry only; no switching 30 mA Disabled (VCC ≤ 2.8V) 900 µA VCC supply current INTERNALLY GENERATED SUPPLY VOLTAGE VDD33 voltage range VDD33 3.0 3.3 VDD33 output current 3.6 2 mA DIGITAL I/O PINS (POK, SYNC) Input high voltage 2.0 5.5 V Input low voltage 0 0.8 V 2.4 VDD33 V Output low voltage 0.4 V Input leakage current ±1 µA Output current - source 2.0 mA Output current - sink 2.0 mA Output high voltage DIGITAL I/O PIN (CTRL) Input high voltage 2.0 3.6 V Input low voltage -0.3 0.8 V CTRL response delay (stop) Configurable polarity; extra turn-off delay configurable (assumes 0 s turn-off delay) 150 µs Page 8 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 PARAMETER SYMBOL TEST CONDITIONS MIN Configurable polarity; extra turn-on delay configurable (assumes 0 s turn-on delay) CTRL response delay (start) TYP MAX 250 UNITS µs HKADC INPUT PINS (VINSEN, VCCSEN, ADDR0 AND ADDR1) Input voltage 0 1.44 V PWM AND SYNCHRONIZATION PWM output voltage high 2.4 V PWM output voltage low 0.4 V PWM tristate leakage ±1 µA PWM pulse width 30 Resolution ns 163 ps Switching frequency – EM2130L fSW With internal oscillator 800 kHz Switching frequency – EM2130H fSW With internal oscillator 1333 kHz Percent of nominal switching frequency SYNC frequency range SYNC pulse width ±12.5 25 % ns OUTPUT VOLTAGE SENSE, REPORTING, AND MANAGEMENT Output voltage adjustment range Output voltage setpoint accuracy Output set-point resolution EM2130L 0.7 1.325 V EM2130H 1.35 3.6 V -0.5 +0.5 % EM2130L 0˚C < TA < 85˚C EM2130L -40˚C < TA < 85˚C -1 +1 % EM2130H -40˚C < TA < 85˚C -1 +1 % EM2130L 1.5 mV Line regulation 0.007 mV/V Load regulation 0.07 mV/A 5 ms Output voltage startup delay From VCC valid, to start of output voltage ramp, if configured to regulate from power on reset, and TON_DELAY is set to 0. Output voltage ramp delay (TON_DELAY & TOFF_DELAY) Configurable, no VOUT pre-bias condition. VTRACK ramp rate 0 500 ms 2.0 V/ms Page 9 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 PARAMETER SYMBOL VTRACK range TEST CONDITIONS Without resistor divider MIN TYP 0 VTRACK offset voltage MAX UNITS 1.4 V ±100 mV OUTPUT CURRENT SENSE, REPORTING, AND MANAGEMENT ±1.5 A ±1 A ±5 °C 0.22 °C PVIN UV threshold 3.96 V PVIN OV threshold 16.5 V Current sense reporting accuracy 25°C < TA < 85°C IOUT > 5A, TA = 25°C TEMPERATURE SENSE, REPORTING, AND MANAGEMENT Temperature reporting accuracy Resolution FAULT MANAGEMENT PROTECTION FEATURES VOUT OV threshold Percentage of output voltage 115 % VOUT UV threshold Percentage of output voltage 85 % IOUT OCP With 45A OCP setting 40 OTP threshold 50 A 120 °C OTP hysteresis Fixed. 85 % POK threshold On level 95 % POK threshold Off level 90 % SERIAL COMMUNICATION PMBUS DC CHARACTERISTICS Input voltage – high (VIH) SCL and SDA Input voltage – low (VIL) SCL and SDA Input leakage current SCL, SDA, SALRT, and CTRL. Output voltage – low (VOL) Nominal bus voltage 1.11 V 0.8 V 10 µA SDA and SALRT at rated pullup current of 20mA. 0.4 V SCL, SDA, and SALRT termination voltage. 3.6 V -10 Page 10 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Typical Performance Characteristics All the performance curves are measured with EM2130 evaluation board at 25°C ambient temperature unless otherwise noted. The output capacitors configuration for the evaluation board is 2 x 470 µF (3 mΩ ESR) + 4 x 100 µF (Ceramic) + 4 x 47 µF (Ceramic). Efficiency, VIN = 12V Efficiency, VIN = 5V EM2130L Thermal Derating, No Airflow EM2130H Thermal Derating, No Airflow EM2130L Line Regulation, VOUT = 0.9V EM2130L Load Regulation, VOUT = 0.9V Page 11 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Typical Performance Characteristics (Continued) Start-up/Shutdown, PVIN At No Load, 20 ms/div Start-up/Shutdown, PVIN At 30A Load, 20 ms/div PVIN PVIN VOUT VOUT PWM PWM IOUT IOUT PVIN and PWM: 3 V/div, VOUT: 300 mV/div, IOUT: 10 A/div PVIN and PWM: 3 V/div, VOUT: 300 mV/div, IOUT: 10 A/div Start-up/Shutdown, CTRL At No Load, 5 ms/div Start-up/Shutdown, CTRL At 30A Load, 5 ms/div CTRL CTRL VOUT VOUT PWM PWM IOUT IOUT CTRL: 1 V/div, PWM: 3 V/div, VOUT: 300 mV/div, IOUT: 10 A/div CTRL: 1 V/div, PWM: 3 V/div, VOUT: 300 mV/div, IOUT: 10 A/div Start-up Into 0.6V Pre-Bias With PVIN, 5 ms/div Start-up Into 0.6V Pre-Bias With CTRL, 5 ms/div PVIN CTRL VOUT VOUT PWM PWM IOUT IOUT PVIN: 3 V/div, PWM: 3 V/div, VOUT: 300 mV/div, IOUT: 10 A/div CTRL: 1 V/div, PWM: 3 V/div, VOUT: 300 mV/div, IOUT: 10 A/div Page 12 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Typical Performance Characteristics (Continued) Output Voltage Ripple, No Load Output Voltage Ripple, 30A Load VOUT VOUT IOUT IOUT VIN = 12V, VOUT = 0.9V 1 µs/div, VOUT: 10 mV/div, 20 MHz bandwidth VIN = 12V, VOUT = 0.9V 1 µs/div, VOUT: 10 mV/div, 20 MHz bandwidth Output Voltage Transient Response, Load Step From 0A To 15A Output Voltage Transient Response, Load Step From 15A To 30A VOUT VOUT IOUT IOUT VIN = 12V, VOUT = 0.9V, 100µs/div VOUT: 30 mV/div, IOUT: 5 A/div, 15 A/µs VIN = 12V, VOUT = 0.9V, 100µs/div VOUT: 30 mV/div, IOUT: 5 A/div, 15 A/µs Output Voltage Transient Response, Load Step From 0A To 15A Output Voltage Transient Response, Load Step From 0A To 15A VOUT VOUT IOUT IOUT VIN = 12V, VOUT = 0.9V, 2µs/div VOUT: 10 mV/div, IOUT: 5 A/div, 100 A/µs VIN = 12V, VOUT = 0.9V, 10µs/div VOUT: 10 mV/div, IOUT: 5 A/div, 1 A/µs Page 13 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 VSENP PVIN Average Current Sensing Digital Control Loop VFB Adaptive Digital Controller FLASH ADC VSENN PWM SYNC Functional Block Diagram VTRACK Power Train DAC Sequencer OC Detection OV/UV Detection DAC PWM Configurable Error Handler PWM VOUT DRIVER LOGI C EN OT Detection Vin OV/UV Detection NVM (OTP) 1.8V Reg Digital RTUNE RVSET GPIO SMBus SCL Clock Gen 3.3V Reg SALRT SDA CTRL POK VINSEN PGND HKADC PVCC ADDR0 1.8V Reg Analog AGND CPU Core VCCSEN ADDR1 VREF VDD33 Int. Temp Sense VCC Bias Current Source Figure 2: Functional Block Diagram Functional Description FUNCTIONAL DESCRIPTION: DEFAULT CONFIGURATION The EM2130 is a single output digital PowerSoC synchronous step-down converter with advanced digital control techniques, capable of supplying up to 30A of continuous output current. The PowerSoC includes integrated power MOSFETs, a high-performance inductor and a digital controller which offers a PMBus version 1.2 compliant interface to support an extensive suite of telemetry, configuration and control commands. In the default configuration, the EM2130 requires only two resistors to set the output voltage and select from preconfigured digital compensators. This easy-to-use default configuration allows the user to tune the EM2130 to meet the most demanding accuracy and load transient requirements without requiring any programming or digital interface. The following sections describe the default configuration. Refer to the Advanced Configuration section for details on the many ways the EM2130 may be customized and configured through the PMBus interface. In order to optimize size versus efficiency over a wide range of operating conditions, there are two module variants – a low output voltage variant EM2130L01 (0.7V ≤ VOUT ≤ 1.325V) which operates at 800KHz and a high output voltage variant EM2130H01 (1.35V ≤ VOUT ≤ 3.6V) which operates at 1.33MHz. Page 14 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 The advanced digital control loop works as a voltage-mode controller using a PID-type compensation. The basic structure of the controller is shown in Figure 3. The EM2130 controller features two PID compensators for steady-state operation and fast transient operation. Fast, reliable switching between the different compensation modes ensures good transient performance and quiet steady state performance. The EM2130 has been pre-programmed with a range of default compensation coefficients which lets the user select the best compensation for the best transient response and stability for the output capacitance of the system. The EM2130 uses two additional technologies to improve transient performance. First, the EM2130 uses over-sampling techniques to acquire fast, accurate, and continuous information about the output voltage so that the device can react quickly to any changes in output voltage. Second, a non-linear gain adjustment is applied during large load transients to boost the loop gain and reduce the settling time. Coefficients Steady-State Operation Mode Detection Digital Error Signal Transient Digital PID Compensator Non-linear Gain Duty Cycle Figure 3: Simplified Block Diagram Of The Digital Compensation In the default configuration, the EM2130 offers a complete suite of fault warnings and protections. Input and output Under Voltage Lock-Out (UVLO) and Over Voltage Lock-Out (OVLO) conditions are continuously monitored. A dedicated ADC is used to provide fast and accurate current information over the switching period allowing for fast Over-Current Protection (OCP) response. Over Temperature Protection (OTP) is accomplished by direct monitoring of the device’s internal temperature. POWER ON RESET The EM2130 employs an internal power-on-reset (POR) circuit to ensure proper start-up and shut down with a changing supply voltage. Once the VCC supply voltage increases above the POR threshold voltage, the EM2130 begins the internal start-up process. Upon its completion, the device is ready for operation. Two separate input voltage supplies are necessary to operate, PVIN (4.5V to 16V) and VCC (4.75V to 5.25V). Both of these voltage rails must be monitored for proper power-up and to protect the power MOSFETs under various input power fault conditions. A voltage divider on each input voltage supply connected to VINSEN for the power rail (PVIN) and VCCSEN for the supply rail (VC) is used for digital monitoring of the supplies. As illustrated in Figure 4, the values of resistors R1, R2, R3 and R4 are chosen so the internal monitor ADC does not saturate within the appropriate ranges. This allows the EM2130 telemetry to report when the recommended operation voltage has been exceeded. Page 15 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 It is mandatory that the listed resistors values are used in order to ensure proper operation with the EM2130 default configuration. The resistors used must be R1=11 kΩ, R2=1 kΩ, R3=10 kΩ and R4=3.3 kΩ, using 1% tolerance or better resistors. If these values are not used then the EM2130 will read incorrect values for both PVIN and VCC. Digital filtering is provided inside the EM2130 but if additional filtering is needed due to high noise on either rail, a capacitor can be connected between each pin (VINSEN & VCCSEN) and ground to maintain high accuracy. VCC EM2130 R3 10 k PVIN VCCSEN R4 3.3 k R1 11 k VINSEN R2 1k AGND Figure 4: VINSEN And VCCSEN Input Resistor Dividers The EM2130 also uses the PVIN monitor for input voltage feed-forward, which eliminates variations in the output voltage due to sudden changes in the input voltage supply. It does this by immediately changing the duty cycle to compensate for the input supply variation by normalizing the DC gain of the loop. SETTING THE OUTPUT VOLTAGE Differential remote sensing provides for precise regulation at the point of load. One of thirty output voltages may be selected in the default configuration, based on a resistor connected to the RVSET pin. At power-up, an internal current source biases the resistor and the voltage is measured by an ADC to decode the Vout selection. Use the RVSET tables (Table 8 and Table 9) for the details of VOUT selection and RVSET values. EM2130 RDIV1 VSENP CA VOUT RDIV2 VSENN PGND Figure 5: Output Voltage Sense Circuitry The digital control loop ADC of the low voltage EM2130L01 supports direct output voltage feedback connection over the entire VOUT range. For the high output voltage EM2130H01, a feedback divider is required as shown in Figure 5. The resistor values in Table 7 are required as a function of the output voltage selection. It is mandatory that the listed resistor values are used, use of other values may result in poor regulation performance as these values are expected in the EM2130 default configuration. Resistors with tight tolerances are recommended to maintain output voltage accuracy. Page 16 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 The resistors in the feedback path also form a low-pass filter with the internal capacitor, CA, for removing high-frequency disturbances from the sense signals. Place these components as close as possible to the EM2130 for best filtering performance. Table 7: Output Voltage Feedback Component Module VOUT RDIV1 RDIV2 EM2130L01 0.7V ≤ VOUT ≤ 1.325V 2 kΩ Open EM2130H01 1.35V ≤ VOUT ≤ 2.6V 2 kΩ 2 kΩ EM2130H01 2.6V < VOUT ≤ 3.6V 2 kΩ 1 kΩ Table 8: Supported Configuation Voltage Values For EM2130L01 Output Voltage RVSET Resistor VOUT External Resistor Divider 0kΩ Reserved R1DIV = 2kΩ, R2DIV = open 0.392kΩ Reserved R1DIV = 2kΩ, R2DIV = open 0.576kΩ Reserved R1DIV = 2kΩ, R2DIV = open 0.787kΩ Reserved R1DIV = 2kΩ, R2DIV = open 1.000kΩ 1.325V R1DIV = 2kΩ, R2DIV = open 1.240kΩ 1.3V R1DIV = 2kΩ, R2DIV = open 1.500kΩ 1.275V R1DIV = 2kΩ, R2DIV = open 1.780kΩ 1.25V R1DIV = 2kΩ, R2DIV = open 2.100kΩ 1.225V R1DIV = 2kΩ, R2DIV = open 2.430kΩ 1.2V R1DIV = 2kΩ, R2DIV = open 2.800kΩ 1.175V R1DIV = 2kΩ, R2DIV = open 3.240kΩ 1.15V R1DIV = 2kΩ, R2DIV = open 3.740kΩ 1.12V R1DIV = 2kΩ, R2DIV = open 4.220kΩ 1.1V R1DIV = 2kΩ, R2DIV = open 4.750kΩ 1.075V R1DIV = 2kΩ, R2DIV = open 5.360kΩ 1.05V R1DIV = 2kΩ, R2DIV = open 6.040kΩ 1.03V R1DIV = 2kΩ, R2DIV = open 6.810kΩ 1.0V R1DIV = 2kΩ, R2DIV = open 7.680kΩ 0.975V R1DIV = 2kΩ, R2DIV = open 8.660kΩ 0.95V R1DIV = 2kΩ, R2DIV = open 9.530kΩ 0.925V R1DIV = 2kΩ, R2DIV = open 10.500kΩ 0.9V R1DIV = 2kΩ, R2DIV = open 11.800kΩ 0.875V R1DIV = 2kΩ, R2DIV = open 13.000kΩ 0.85V R1DIV = 2kΩ, R2DIV = open Page 17 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 RVSET Resistor VOUT External Resistor Divider 14.300kΩ 0.825V R1DIV = 2kΩ, R2DIV = open 15.800kΩ 0.8V R1DIV = 2kΩ, R2DIV = open 17.400kΩ 0.775V R1DIV = 2kΩ, R2DIV = open 19.100kΩ 0.75V R1DIV = 2kΩ, R2DIV = open 21.000kΩ 0.725V R1DIV = 2kΩ, R2DIV = open 23.200kΩ 0.7V R1DIV = 2kΩ, R2DIV = open Table 9: Supported Configuration Voltage Values For EM2130H01 Output Voltage RVSET Resistor VOUT External Resistor Divider 0kΩ Reserved R1DIV = 2kΩ, R2DIV = 1kΩ 0.392kΩ Reserved R1DIV = 2kΩ, R2DIV = 1kΩ 0.576kΩ 3.3V R1DIV = 2kΩ, R2DIV = 1kΩ 0.787kΩ 3.2V R1DIV = 2kΩ, R2DIV = 1kΩ 1.000kΩ 3.1V R1DIV = 2kΩ, R2DIV = 1kΩ 1.240kΩ 3.0V R1DIV = 2kΩ, R2DIV =1kΩ 1.500kΩ 2.9V R1DIV = 2kΩ, R2DIV = 1kΩ 1.780kΩ 2.8V R1DIV = 2kΩ, R2DIV = 1kΩ 2.100kΩ 2.7V R1DIV = 2kΩ, R2DIV = 1kΩ 2.430kΩ 2.6V R1DIV = 2kΩ, R2DIV = 2kΩ 2.800kΩ 2.5V R1DIV = 2kΩ, R2DIV = 2kΩ 3.240kΩ 2.4V R1DIV = 2kΩ, R2DIV = 2kΩ 3.740kΩ 2.3V R1DIV = 2kΩ, R2DIV = 2kΩ 4.220kΩ 2.2V R1DIV = 2kΩ, R2DIV = 2kΩ 4.750kΩ 2.1V R1DIV = 2kΩ, R2DIV = 2kΩ 5.360kΩ 2.0V R1DIV = 2kΩ, R2DIV = 2kΩ 6.040kΩ 1.9V R1DIV = 2kΩ, R2DIV = 2kΩ 6.810kΩ 1.8V R1DIV = 2kΩ, R2DIV = 2kΩ 7.680kΩ 1.75V R1DIV = 2kΩ, R2DIV = 2kΩ 8.660kΩ 1.7V R1DIV = 2kΩ, R2DIV = 2kΩ 9.530kΩ 1.65V R1DIV = 2kΩ, R2DIV = 2kΩ 10.500kΩ 1.6V R1DIV = 2kΩ, R2DIV = 2kΩ 11.800kΩ 1.55V R1DIV = 2kΩ, R2DIV = 2kΩ 13.000kΩ 1.5V R1DIV = 2kΩ, R2DIV = 2kΩ Page 18 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 RVSET Resistor VOUT External Resistor Divider 14.300kΩ 1.475V R1DIV = 2kΩ, R2DIV = 2kΩ 15.800kΩ 1.45V R1DIV = 2kΩ, R2DIV = 2kΩ 17.400kΩ 1.425V R1DIV = 2kΩ, R2DIV = 2kΩ 19.100kΩ 1.4V R1DIV = 2kΩ, R2DIV = 2kΩ 21.000kΩ 1.375V R1DIV = 2kΩ, R2DIV = 2kΩ 23.200kΩ 1.35V R1DIV = 2kΩ, R2DIV = 2kΩ ENABLE And OUTPUT START-UP BEHAVIOR The control pin (CTRL) provides a means to enable normal operation or to shut down the device. When the CTRL pin asserted (high) the device will undergo a normal soft-start. A logic low on this pin will power the device down in a controlled manner. Dedicated pre-biased start-up logic ensures proper start-up of the power converter when the output capacitors are pre-charged to a non-zero output voltage. Closed-loop stability is ensured during this period. The typical power sequencing, including ramp up/down and delays is shown in Figure 6. Figure 6: Power Sequencing POWER OK The EM2130 has a push-pull power good indicator at its output pin, POK. There is no need to add a pull-up resistor. When de-asserted, POK indicates that the output voltage is below a certain threshold value. The POK threshold is set to 90% of the programmed output voltage in the default configuration. When asserted, POK indicates that the output is in regulation, and no major faults are present. As a result, POK de-asserts during any serious fault condition where power conversion stops and re-asserts when the output voltage recovers. COMPENSATING THE DIGITAL CONTROL LOOP To improve the transient performance for a typical point-of-load design, it is common to add output capacitance to the converter. This moves the output LC resonant frequency lower as capacitance increases Page 19 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 which results in lower bandwidth, lower phase margin, and longer settling times unless the control loop is compensated for added capacitance. However, with EM2130 the user does not need to be concerned with, or even understand, the details of control loop compensation techniques. The default configuration allows users to select from preconfigured PID control loop settings (known as compensators) through the use of pin-strapping. A single resistor from the RTUNE pin to AGND informs the EM2130 of the compensator selection. The selection of the compensator is driven first by the type of output capacitors used, as the ESL and ESR of different capacitor types demands different PID coefficients to optimize transient deviation and recovery characteristics. An all ceramic output capacitor design requires a different compensator than a design with a combination of ceramic and polymer capacitors, i.e. POSCAP. Table 11 shows several output capacitor part number recommendations. The five different compensators can then be subdivided into groups of six each whereby the initial capacitance value in the appropriate compensator can be scaled upwards by multiplication factor M to match the additional capacitance. Page 20 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Table 10: RTUNE configuration table for EM2130L01 Compensator Description Polymer Aluminum (SP-CAP) and Ceramic MLCC Output Capacitors Base capacitance = 1 x 470µF (Polymer) + 2 x 100µF (Ceramic) + 2 x 47µF (Ceramic) All MLCC Ceramic Output Capacitors Base capacitance = 8 x 100µF POSCAP and Ceramic MLCC Output Capacitors Base capacitance = 4 x 330 µF (POSCAP) + 2 x 100 µF (Ceramic) COUT RTUNE Resistor Multiplication factor (M) Typical Deviation With 15A Load Step Base 0kΩ 1 ± 5% 2 x Base 0.392kΩ 2 ± 3% 3 x Base 0.576kΩ 3 4 x Base 0.787kΩ 4 5 x Base 1.000kΩ 5 6 x Base 1.240kΩ 6 Base 1.500kΩ 1 1.5 x Base 1.780kΩ 1.5 2 x Base 2.100kΩ 2 3 x Base 2.430kΩ 3 4 x Base 2.800kΩ 4 4.5 x Base 3.240kΩ 4.5 ± 1.5% Base 3.740kΩ 1 ± 5% 1.5 x Base 4.220kΩ 1.5 2 x Base 4.750kΩ 2 2.5 x Base 5.360kΩ 2.5 3 x Base 6.040kΩ 3 3.5 x Base 6.810kΩ 3.5 ± 1.5% ± 5% ± 3% ± 3% ± 1.5% 7.680kΩ 8.660kΩ 9.530kΩ 10.500kΩ 11.800kΩ Reserved for User Programmed Compensation Values 13.000kΩ 14.300kΩ 15.800kΩ 17.400kΩ 19.100kΩ 21.000 kΩ 23.200 kΩ Page 21 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Table 11: Recommended Output Capacitors Description Manufacturer P/N 470µF, 2.5V, ESR 3mΩ SP-CAP Panasonic EEFGX0E471R 330µF, 6.3V, ESR 9 mΩ POSCAP Panasonic 6TPF330M9L 330µF, 2.5V, ESR 9 mΩ POSCAP Kemet T520B337M2R5ATE009 100µF, 6.3V, X5R, 1206 Ceramic Kemet C1206C107M9PACTU 47µF, 6.3V, X5R 1206 Ceramic Murata GRM31CR60J476ME19L OUTPUT CAPACITOR RECOMMENDATION The output filter capacitors can be configured as a combination of local output filter capacitors that absorb the AC switching currents generated by the converter and bulk decoupling capacitors close to the device supply pins; this recommendation refers only to the local filter capacitor requirements. Please consult the documentation for your particular FPGA, ASIC, processor, or memory block for the bulk decoupling capacitor requirements. Table 12 shows the minimum local decoupling capacitors requirements. Two of the local output filter capacitors can be mounted on the PCB back-side to reduce the solution size. An example of the minimum footprint layout is shown in Figure 7. The output filter capacitors should use X5R, X7R, or equivalent dielectric with an appropriate voltage rating. Table 12: Local Decoupling Requirements Symbol Capacitor Recommendations CIN 3 x 22µF (1206) + 1 x 10µF (0805) or 4 x 22µF (1206) COUT 4 x 100µF (1206) INPUT CAPACITOR RECOMMENDATION The EM2130 input should be decoupled with at least three 22µF 1206 case size and one 10µF 0805 case size MLCC ceramic capacitors or four 22µF MLCC 1206 case size ceramic capacitors. More bulk capacitor may be needed only if there are long inductive traces at the input source or there is not enough source capacitance. These input decoupling ceramic capacitors can be mounted on the PCB back-side to reduce the solution size. These input filter capacitors should have the appropriate voltage rating for the input voltage on PVIN, and use a X5R, X7R, or equivalent dielectric rating. Y5V or equivalent dielectric formulations must not be used as these lose too much capacitance with frequency, temperature and bias voltage. The PVCC pin provides power to the gate drive of the internal high/low side power MOSFETs. The VCC pin provides power to the internal digital controller. These two power inputs share the same supply voltage (5V nominal), and should be bypassed with a single 2.2µF MLCC capacitor. To avoid switching noise injection from PVCC to VCC, it is recommended a ferrite bead is inserted between PVCC and VCC pins as shown Figure 16. Page 22 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Figure 7: Top And Bottom Layer Of The Minimum Footprint Layout Example PROTECTION FEATURES The EM2130 offers a complete suite of programmable fault warnings and protections. Input and output Under Voltage Lock-Out (UVLO) and Over Voltage Lock-Out (OVLO) conditions are continuously monitored. A dedicated ADC is used to provide fast and accurate current information during the entire switching period to provide fast Over-Current Protection (OCP) response. To prevent damage to the load, the EM2130 utilizes an output over-voltage protection circuit. The voltage at VSENP is continuously compared with a configurable threshold using a high-speed analog comparator. If the voltage exceeds the configured threshold, a fault response is generated and the PWM output is turned off. The output voltage is also sampled, filtered, and compared with an output over-voltage warning threshold. If the output voltage exceeds this threshold, a warning is generated and the preconfigured actions are triggered. The EM2130 also monitors the output voltage with two lower thresholds. If the output voltage is below the under-voltage warning level and above the under-voltage fault level, an output voltage undervoltage warning is triggered. If the output voltage falls below the fault level, a fault event is generated. Similar to output over and under voltage protection, the EM2130 monitors the input voltage at VINSEN continuously with a configurable threshold. If the input voltage exceeds the over voltage threshold or is below the under voltage threshold, the default response is generated. Over Temperature Protection (OTP) is based on direct monitoring of the device’s internal temperature. If the temperature exceeds the OTP threshold, the device will enter a soft-stop mode slowly ramping the output voltage down until the temperature falls below the default recovery temperature. The default fault response is zero delay and latch off for most fault conditions. The CTRL pin may be cycled to clear the latch. Table 13 summarizes the default configurations that have been pre-programmed to the device. Page 23 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Table 13: Fault Configuration Overview Signal Output Over-Voltage Output Under-Voltage Input Over-Voltage Input Under-Voltage Over-Current Internal OverTemperature Fault Level Default Response Type Warning Fault High-impedance Warning Fault High-impedance Warning Fault High-impedance Warning Fault High-impedance Warning Fault High-impedance Warning Fault Soft Off Delay (ms) Retries 0 None 0 None 0 None 0 Infinity 0 None 0 Infinity FUNCTIONAL DESCRIPTION: ADVANCED CONFIGURATION All EM2130 modules are delivered with a pre-programmed default configuration, allowing the module to be powered up without a need to configure the device or even the need for the GUI to be connected. However, a PMBus version 1.2 compliant interface allows access to an extensive suite of digital communication and control commands. This includes configuring the EM2130 for optimum performance, setting various parameters such as output voltage, and monitoring and reporting device behavior including output voltage, output current, and fault responses. The device may be reconfigured multiple times without storing the configuration into the non-volatile memory (NVM). Any configuration changes will be lost upon power-on reset unless specifically stored into NVM using either STORE_DEFAULT_ALL or STORE_DEFAULT_CODE PMBus commands. Please see Table 17 for more details. For RVSET and RTUNE configurations, there is no reprogramming permitted. After writing a new configuration to NVM, the user may still make changes to the device configuration through the PMBus interface; however, now upon power cycling the device, the stored NVM configuration will be recalled upon power-up rather than the factory default configuration of the EM2130. The NVM configuration can be stored three times in its entirety. However, the consumption of the available NVM is dynamic, based on the configuration parameters that have actually changed. The unused NVM information is given in the GUI or through the manufacture specific command MFR_STORE_PARAMS_REMAINING. INTEL DIGITAL POWER CONFIGURATOR The Intel Enpirion Digital Power Configurator is a Graphical User Interface (GUI) software which allows the EM2130 to be controlled via a USB interface to a host computer. Page 24 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 The user can view the power supply’s status, I/O voltages, output current and fault conditions detected by the device, program settings to the converter, and issue PMBus commands using the GUI. Most of the parameters (for example, VOUT turn on/off time, protection and fault limits) can be configured and adjusted within the GUI environment. These parameters can also be configured outside of the GUI environment using the relevant PMBus™ commands. The GUI also allows the user to easily create, modify, test and save a configuration file which may then be used to permanently burn the configuration into NVM within a production test environment. ALTERNATIVE OUTPUT VOLTAGE CONTROL METHODS In the default configuration, output voltage selection is determined at power-up by the pin-strapped resistor RVSET. This functionality can be disabled using the PMBus command MFR_PIN_CONFIG. When RVSET is disabled, the output voltage will be determined by the nominal output voltage setting in the user configuration. The EM2130 supports a subset of the output voltage commands outlined in the PMBus specification. For example, the output voltage can be dynamically changed using the PMBus command VOUT_COMMAND. When the output is being changed by the PMBus command, power good (POK) remains at a logic high. POWER SEQUENCING AND THE CONTROL (CTRL) PIN Three different configuration options are supported to enable the output voltage. The device can be configured to turn on after an OPERATION_ON command, via the assertion of the CTRL pin or a combination of both per the PMBus convention. The EM2130 supports power sequencing features including programmable ramp up/down and delays. The typical sequence of events is shown in Figure 6 and follows the PMBus standard. The individual timing values shown in Figure 6 and Figure 8 can be configured using the appropriate configuration setting in Intel Digital Power Configurator GUI. PRE-BIASED START-UP AND SOFT-STOP In systems with complex power architectures, there may be leakage paths from one supply domain which charge capacitors in another supply domain leading to a pre-biased condition on one or more power supplies. This condition is not idea and can be avoided through careful design, but is generally not harmful. Attempting to discharge the pre-bias is not advised as it may force high current though the leakage path. The EM2130 includes features to enable and disable into pre-biased output capacitors. If the output capacitors are pre-biased when the EM2130 is enabled, start-up logic in the EM2130 ensures that the output does not pull down the pre-biased voltage and the tON_RISE timing is preserved. Closed-loop stability is ensured during the entire start-up sequence under all pre-bias conditions. The EM2130 also supports pre-biased off, in which the output voltage ramp down to a user-defined level (VOFF_nom) rather than to zero. After receiving the disable command, via PMBus command or the CTRL pin, the EM2130 ramps down the output voltage to the predefined value. Once the value is reached, the output driver into a tristate mode to avoid excessive currents through the leakage path. Page 25 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Figure 8: Power Sequencing With Non-Zero Off Voltage VOLTAGE TRACKING The EM2130 can control the output voltage based on the external voltage applied to the VTRACK pin, thus allowing sequencing of the output voltage from an external source. Pre-bias situations are also supported. The VTRACK pin voltage is a single-ended input referenced to analog ground. Tracking mode is disabled by default, but it can be enabled using the GUI software or via the manufacturer-specific PMBus command, MFR_FEATURES_CTRL (see Table 17). If VTRACK is not intended to be used, tie the VTRACK pin low or leaving it floating. VTRACK VTRACK VOUT Pre-bias t Figure 9: Power Sequencing Using VTRACK With Bias Voltage On VOUT The set point voltage for the EM2130 is defined by the lower value of the VOUT setting or an external voltage applied to the VTRACK pin. If the VTRACK voltage rises above the VOUT set point voltage, then the final output voltage will be limited by the VOUT setting. If the tracking feature is enabled, but the VTRACK pin is tied low or floating, then the output will never start as the VTRACK pin input is always the lower value and will always be in control. Conversely, if tracking is enabled, but VTRACK is tied high, the output will start but will follow the VOUT set point, not the VTRACK pin. If tracking is used for sequencing, it is recommended that the VTRACK signal is kept greater than the VOUT voltage. This ensures that the internal VOUT set point is used as the final steady-state output voltage and accuracy is not a function of the externally applied VTARCK voltage. The tracking function will override a programmed pre-bias off level (VOFF_nom). Page 26 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 VFB VTRACK DAC + Set-Point (Defined by lower input value) Figure 10: VTRACK Circuitry The following figures demonstrate ratio-metric and simultaneous sequencing of the output voltage, which can be accomplished by applying an appropriate external voltage on the VTRACK pin. When using the VTRACK feature, the sequencing will be ratio-metric as shown in Figure 13 if an external resistor network is used at the VTRACK pin as shown Figure 11. If no external resistors are used, the output sequence is simultaneous as shown in Figure 14. In the event that a feedback divider is not required, (such as when VOUT  1.4V) but the tracking voltage applied to VTRACK is greater than 1.4V, then a 2kΩ resistor is required in series with the VTRACK pin to minimize leakage current as shown in Figure 12. In applications where a voltage divider is required on the output voltage, a voltage divider consisting of the same values is also required for the VTRACK pin. Figure 11: VTRACK Sense Circuitry with Resistor Divider Figure 12: VTRACK Sense Circuitry (Input > 1.4V) Page 27 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 V VTRACK VOUT t Figure 13: Ratiometric Sequencing Using VTRACK V VTRACK VOUT t Figure 14: Simultaneous Sequencing Using VTRACK CLOCK SYNCHRONIZATION The EM2130’s PWM synchronization feature allows the user to synchronize the switching frequency of multiple devices. The SYNC pin can be configured as an input or an output. When the SYNC pin is configured as input clock, the external clock need to be available before the EM2130 is enabled. The EM2130 will only lock to the external clock within 1ms after the device is enabled. After 1 ms the device can be re-synchronized to the external clock signal by toggling VOUT or via PMBus MFR_RESYNC command. When the SYNC pin is configured as an output clock (sync out), there is no requirement to provide an external clock to allow synchronization. The EM2130 SYNC functionality maybe configured as an input or an output using Intel’s GUI software or via the manufacturer-specific PMBus command, MFR_PIN_CONFIG. The default configuration for synchronization control is OFF. TEMPERATURE AND OUTPUT CURRENT MEASUREMENT The EM2130 temperature sense block provides the device and the system with precision temperature information over a wide range of temperatures (-40°C to +150°C). The temperature sense block measures the digital controller temperature, which will be slightly lower than the powertrain junction temperature. The EM2130 monitors output current by real-time, temperature compensated DCR current sensing across the inductor. This real-time current waveform is then digitally filtered and averaged for accurate telemetry, fault warning, and management. Factory calibration has been performed for every EM2130 device to improve measurement accuracy over the full output current range. This allows the EM2130 to correct for DCR manufacturing variations. Page 28 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 For over-current protection, an unfiltered ADC is used in order to minimize delays in protecting the device. Because this measurement is unfiltered, the accuracy of the protection threshold is less than that of the average current reading. PROTECTION AND FAULT RESPONSE The EM2130 monitors various signals during operation in order to detect fault conditions. Measured and filtered signals are compared to a configurable set of warnings and fault thresholds. In typical usage, a warning sets a status flag, but does not trigger a response; whereas a fault sets a status flag and generates a response. The assertion of the SMBALERT signal can be configured to individual application requirements. The EM2130 supports a number of different response types depending on the fault detected. In the default configuration, the EM2130 responds to an over temperature event by ramping down VOUT in a controlled manner at a slew rate defined by the TOFF_FALL value. This response type is termed “Soft-Off”. The final state of the output signals depends on the value selected for VOFFnom. For all other faults the EM2130 will respond by immediately turning off both the top-side MOSFET and lowside MOSFET. This response type is termed “High-Impedance”. For each fault response, a delay and a retry setting can be configured. If the delay-to-fault value is set to non-zero, the EM2130 will not respond to a fault immediately. Instead it will delay the response by the configured value and then reassesses the signal. If the fault remains present during the delay time, the appropriate response will be triggered. If the fault is no longer present, the previous detection will be disregarded. If the delay-to-retry value is set to non-zero, the EM2130 will not attempt to restart immediately after fault detection. Instead it will delay the restart by the configured value. If the fault is still present when attempting to restart, the appropriate response will be triggered. If the fault is no longer present, the previous detection will be disregarded. If the delay-to-fault is a non-zero value, then the delay-to-retry value will be a factor of 100 times greater than the delay-to-fault value. The retry setting, i.e. the number of EM2130 restarts after a fault event, can be configured. This number can be between zero and six. A setting of seven represents infinite retry operation. This setting is commonly known as “Hiccup Mode.” Page 29 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 PMBus Functionality INTRODUCTION The EM2130 supports the PMBus protocol (version 1.2) to enable the use of configuration, monitoring, and fault management features during run-time. The PMBus host controller is connected to the EM2130 via the PMBus pins (SDA, SCL). A dedicated SMBALERT pin is provided to notify the host that new status information is present. The EM2130 supports packet correction (PEC) according to the PMBus™ specification. The EM2130 supports more than 60 PMBus commands in addition to several manufacturer specific commands related to output voltage, faults, telemetry, and more. The EM2130 provides a PMBus set of synchronous communication lines, with serial clock input (SCL), serial data I/O (SDA), and serial alarm output (SALRT) pins. The communication lines provide 3.6V-tolerance, 1.8V I/O compatibility and open-drain outputs (SDA, SCL and SALRT). The communication lines require external pull-up resistors; typical applications require pull-up resistors on each end of the communication lines (typically values of 10 kΩ each), connected to VDD33 or an alternative termination voltage. Please refer to the PMBus specification (www.pmbus.org) for full details. The EM2130 provides configurable behavior for the SALRT pin to allow users to determine which fault or warning conditions to communicate over the SALRT line. The default behavior of the controller ensures that any fault or warning results in the EM2130 SALRT pin going low; the alert behavior is enabled for all faults and warnings. You can deselect any of the faults or warnings so when one of these conditions occur, the SALRT pin is not pulled low. The EM2130 provides a PMBus compliant power conversion control signal through input CTRL. You can configure input CTRL through the standard PMBus command ON_OFF_CONFIG. By default configuration, the CTRL pin must be pulled high to enable operation and the PMBus command OPERATION is ignored. You can override this function with the ON_OFF_CONFIG PMBus command. Remote measurement and reporting of telemetry information at the power supply level provides feedback on key parameters such as voltages, current levels, temperature, and energy, and allows reporting of information such as faults and warning flags. With this information, data is collected and analyzed while the power supply is in development, such as in the qualification or verification phases, or in the field, and system level interaction such as power capping is implemented. Several telemetry parameters are supported by standard PMBus commands. The EM2130P supports PMBus output current telemetry through the READ_IOUT command and reports the low-pass filtered, or DC, output current. The standard PMBus command READ_VOUT supports output voltage telemetry. The standard PMBus command READ_VIN supports input voltage telemetry. The EM2130 supports temperature telemetry and reporting through standardized PMBus commands. READ_TEMPERATURE_2 is mapped to the controller die temperature. The standard PMBus command READ_FREQUENCY supports switching frequency monitoring. This command returns the scaled frequency of the PWM output in kHz. Page 30 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 The EM2130 supports the LINEAR data format according to the PMBus specification. Note that in accordance with the PMBus specification, all commands related to the output voltage are subject to the VOUT_MODE settings. A detailed description of the supported PMBus commands supported by the EM2130 can be found in EM2130 Application Note – PMBus Commands Guide. TIMING AND BUS SPECIFICATION tLOW tHIGH tR SCL tBUF tF tHD:DAT tSU:STA tSU:STO tHD:STA SDA S P tSU:DAT P S Figure 15: PMBus Timing Diagram Table 14: EM2130 PMBus Parameters Parameter Symbol PMBus operation frequency Conditions Min Typ Max Units fSMB 10 100 400 kHz Bus free time between start and stop tBUF 1.3 μs Hold time after start condition tHD:STA 0.6 μs Repeat start condition setup time tSU:STA 0.6 μs Stop condition setup time tSU:STO 0.6 μs Data hold time tHD:DAT 300 ns Data setup time tSU:DAT 150* ns Clock low time-out tTIMEOUT Clock low period tLOW 1.3 μs Clock high period tHIGH 0.6 μs Cumulative clock low extend time tLOW:SEXT 25 ms Clock or data fall time tF 300 ns Clock or data rise time tR 300 ns 25 35 ms Note: The EM2130 fully complies with PMBus 1.2 specifications for operation up to 100kHz on SCL. The EM2130 may be operated at frequencies up to at least 400kHz on SCL if tSU:DAT is maintained greater than 150ns. ADDRESS SELECTION VIA EXTERNAL RESISTORS The PMBus protocol uses a 7-bit device address to identify different devices connected to the bus. This address can be selected via external resistors connected to the ADDRx pins. Page 31 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 The resistor values are sensed using the internal ADC during the initialization phase and the appropriate PMBus address is selected. Note that the respective circuitry is only active during the initialization phase; hence no DC voltage can be measured at the pins. The supported PMBus addresses and the values of the respective required resistors are listed in Table 16. If only four devices are used in a system, their respective addresses can alternatively be configured without resistors by connecting the pins to the AGND or VDD33 pin. The PMBus addresses selectable in this fashion are listed in Table 15. Table 15: PMBus Address Selection Without Resistors Address ADDR1 ADDR0 0x0F GND VDD33 0x30 VDD33 GND 0x3F VDD33 VDD33 0x40 GND GND Table 16: Supported Resistor Values For PMBus Address Selection Address (hex) ADDR1 Ω ADDR0 Ω Address (hex) ADDR1 Ω ADDR0 Ω Address (hex) ADDR1 Ω ADDR0 Ω 0x40 0 0 0x2B 1.2 k 12 k 0x56 3.9 k 4.7 k 0x01* 0 680 0x2C 1.2 k 15 k 0x57 3.9 k 5.6 k 0x02* 0 1.2 k 0x2D 1.2 k 18 k 0x58 3.9 k 6.8 k 0x03* 0 1.8 k 0x2E 1.2 k 22 k 0x59 3.9 k 8.2 k 0x04* 0 2.7 k 0x2F 1.2 k 27 k 0x5A 3.9 k 10 k 0x05* 0 3.9 k 0x30 1.8 k 0 0x5B 3.9 k 12 k 0x06* 0 4.7 k 0x31 1.8 k 680 0x5C 3.9 k 15 k 0x07* 0 5.6 k 0x32 1.8 k 1.2 k 0x5D 3.9 k 18 k 0x08* 0 6.8 k 0x33 1.8 k 1.8 k 0x5E 3.9 k 22 k 0x09 0 8.2 k 0x34 1.8 k 2.7 k 0x5F 3.9 k 27 k 0x0A 0 10 k 0x35 1.8 k 3.9 k 0x60 4.7 k 0 0x0B 0 12 k 0x36 1.8 k 4.7 k 0x61* 4.7 k 680 0x0C* 0 15 k 0x37* 1.8 k 5.6 k 0x62 4.7 k 1.2 k 0x0D 0 18 k 0x38 1.8 k 6.8 k 0x63 4.7 k 1.8 k 0x0E 0 22 k 0x39 1.8 k 8.2 k 0x64 4.7 k 2.7 k 0x0F 0 27 k 0x3A 1.8 k 10 k 0x65 4.7 k 3.9 k 0x10 680 0 0x3B 1.8 k 12 k 0x66 4.7 k 4.7 k 0x11 680 680 0x3C 1.8 k 15 k 0x67 4.7 k 5.6 k 0x12 680 1.2 k 0x3D 1.8 k 18 k 0x68 4.7 k 6.8 k 0x13 680 1.8 k 0x3E 1.8 k 22 k 0x69 4.7 k 8.2 k Page 32 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Address (hex) ADDR1 Ω ADDR0 Ω Address (hex) ADDR1 Ω ADDR0 Ω Address (hex) ADDR1 Ω ADDR0 Ω 0x14 680 2.7 k 0x3F 1.8 k 27 k 0x6A 4.7 k 10 k 0x15 680 3.9 k 0x40 2.7 k 0 0x6B 4.7 k 12 k 0x16 680 4.7 k 0x41 2.7 k 680 0x6C 4.7 k 15 k 0x17 680 5.6 k 0x42 2.7 k 1.2 k 0x6D 4.7 k 18 k 0x18 680 6.8 k 0x43 2.7 k 1.8 k 0x6E 4.7 k 22 k 0x19 680 8.2 k 0x44 2.7 k 2.7 k 0x6F 4.7 k 27 k 0x1A 680 10 k 0x45 2.7 k 3.9 k 0x70 5.6 k 0 0x1B 680 12 k 0x46 2.7 k 4.7 k 0x71 5.6 k 680 0x1C 680 15 k 0x47 2.7 k 5.6 k 0x72 5.6 k 1.2 k 0x1D 680 18 k 0x48 2.7 k 6.8 k 0x73 5.6 k 1.8 k 0x1E 680 22 k 0x49 2.7 k 8.2 k 0x74 5.6 k 2.7 k 0x1F 680 27 k 0x4A 2.7 k 10 k 0x75 5.6 k 3.9 k 0x20 1.2 k 0 0x4B 2.7 k 12 k 0x76 5.6 k 4.7 k 0x21 1.2 k 680 0x4C 2.7 k 15 k 0x77 5.6 k 5.6 k 0x22 1.2 k 1.2 k 0x4D 2.7 k 18 k 0x78* 5.6 k 6.8 k 0x23 1.2 k 1.8 k 0x4E 2.7 k 22 k 0x79* 5.6 k 8.2 k 0x24 1.2 k 2.7 k 0x4F 2.7 k 27 k 0x7A* 5.6 k 10 k 0x25 1.2 k 3.9 k 0x50 3.9 k 0 0x7B* 5.6 k 12 k 0x26 1.2 k 4.7 k 0x51 3.9 k 680 0x7C* 5.6 k 15 k 0x27 1.2 k 5.6 k 0x52 3.9 k 1.2 k 0x7D* 5.6 k 18 k 0x28* 1.2 k 6.8 k 0x53 3.9 k 1.8 k 0x7E* 5.6 k 22 k 0x29 1.2 k 8.2 k 0x54 3.9 k 2.7 k 0x7F* 5.6 k 27 k 0x2A 1.2 k 10 k 0x55 3.9 k 3.9 k Note 2: The gray-highlighted addresses with an asterick are reserved by the SMBus specification. PMBUS COMMANDS A detailed description of the PMBus commands supported by the EM2130 can be found in a separate document - EM2130 PMBus Commands Guide. Below, Table 16 lists of all supported PMBus commands. Table 17: List Of Supported PMBus Commands Command Code PMBus Parameter Description 01HEX OPERATION On/off command 02HEX ON_OFF_CONFIG On/off configuration 03HEX CLEAR_FAULTS Clear status information 10HEX WRITE_PROTECT Protect against changes 11HEX STORE_DEFAULT_ALL Copy entire memory into OTP Page 33 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Command Code PMBus Parameter Description 12HEX RESTORE_DEFAULT_ALL Copy entire memory from OTP 13HEX STORE_DEFAULT_CODE Copy single parameter into OTP 14HEX RESTORE_DEFAULT_CODE Copy single parameter from OTP 20HEX VOUT_MODE (Note 3) Exponent of the VOUT_COMMAND value 21HEX VOUT_COMMAND Set output voltage 22HEX VOUT_TRIM Apply a fixed offset voltage 23HEX VOUT_CAL_OFFSET Apply a fixed offset voltage 25HEX VOUT_MARGIN_HIGH Sets maximum value 26HEX VOUT_MARGIN_LOW Sets minimum value 29HEX VOUT_SCALE_LOOP Scalar for output voltage divider 2AHEX VOUT_SCALE_MONITOR Scalar for read-back with output voltage divider 35HEX VIN_ON Input voltage turn on threshold 36HEX VIN_OFF Input voltage turn off threshold 38HEX IOUT_CAL_GAIN Sets ratio of sensed voltage to inductor current 39HEX IOUT_CAL_OFFSET Compensation of current sense offset 40HEX VOUT_OV_FAULT_LIMIT Over-voltage fault limit 41HEX VOUT_OV_FAULT_RESPONSE Over-voltage fault response 42HEX VOUT_OV_WARN_LIMIT Over-voltage warning level 43HEX VOUT_UV_WARN_LIMIT Under-voltage warning level 44HEX VOUT_UV_FAULT_LIMIT Under-voltage fault level 45HEX VOUT_UV_FAULT_RESPONSE Under-voltage fault response 55HEX VIN_OV_FAULT_LIMIT Over-voltage fault limit 56HEX VIN_OV_FAULT_RESPONSE Over-voltage fault response 57HEX VIN_OV_WARN_LIMIT Over-voltage warning level 58HEX VIN_UV_WARN_LIMIT Under-voltage warning level 59HEX VIN_UV_FAULT_LIMIT Under-voltage fault level 5AHEX VIN_UV_FAULT_RESPONSE Under-voltage fault response 5EHEX POWER_GOOD_ON Power good on threshold 5FHEX POWER_GOOD_OFF Power good off threshold 60HEX TON_DELAY Turn-on delay 61HEX TON_RISE Turn-on rise time 62HEX TON_MAX_FAULT_LIMIT Turn-on maximum fault time 64HEX TOFF_DELAY Turn-off delay Page 34 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Command Code PMBus Parameter Description 65HEX TOFF_FALL Turn-off fall time 66HEX TOFF_MAX_WARN_LIMIT Turn-off maximum warning time 78HEX STATUS_BYTE Unit status byte 79HEX STATUS_WORD Unit status word 7AHEX STATUS_VOUT Output voltage status 7BHEX STATUS_IOUT Output current status 7CHEX STATUS_INPUT Input status 7EHEX STATUS_CML Communication and memory status 80HEX STATUS_MFR_SPECIFIC Manufacturer specific status 88HEX READ_VIN Reads input voltage 8BHEX READ_VOUT Reads output voltage 8CHEX READ_IOUT Reads output current 8EHEX READ_TEMPERATURE Reads temperature 95HEX READ_FREQUENCY Reads switching frequency 96HEX READ_POUT Reads output power 98HEX PMBUS™_REVISION PMBus™ revision 99HEX MFR_ID Manufacturer ID 9AHEX MFR_MODEL Manufacturer model identifier 9BHEX MFR_REVISION Manufacturer product revision 9EHEX MFR_SERIAL Serial number A0HEX MFR_VIN_MIN Minimum input voltage A4HEX MFR_VOUT_MIN Minimum output voltage D0HEX MFR_SPECIFIC_00 Write word (once) / Read word – 2 bytes D1HEX MFR_SPECIFIC_01 Write word / read word – 12 bytes D2HEX MFR_READ_VCC Reads VCC voltage D3HEX MFR_RESYNC Active RESYNC DAHEX MFR_RTUNE_CONFIG Gets/sets RTUNE settings DBHEX MFR_VOUT_MARGIN_HIGH Gets/sets Margin High DCHEX MFR_VOUT_MARGIN_LOW Gets/sets Margin Low DDHEX MFR_RTUNE_INDEX Returns index derived from resistor detected on RTUNE pin DEHEX MFR_RVSET_INDEX Returns index derived from resistor detected on RVSET pin Page 35 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Command Code PMBus Parameter Description E0HEX MFR_VOUT_OFF Sets the target turn-off voltage E2HEX MFR_OT_FAULT_LIMIT Over-temperature fault level E3HEX MFR_OT_WARN_LIMIT Over-temperature warning level E5HEX MFR_OT_FAULT_RESPONSE Over-temperature fault response E6HEX MFR_TEMP_ON Over-temperature on level E7HEX MFR_PIN_CONFIG Enable/disable – RTUNE, RVSET, VTRACK and SYNC E9HEX MFR_STORE_CONFIG_ADDR_READ Reads a configuration value EAHEX MFR_STORE_PARAMS_REMAINING Number of STORE_DEFAULT_ALL commands remaining EBHEX MFR_STORE_CONFIGS_REMAINING Number of full configurations remaining ECHEX MFR_STORE_CONFIG_BEGIN Commence programming of OTP EDHEX MFR_STORE_CONFIG_ADDR_DATA Program a configuration value EEHEX MFR_STORE_CONFIG_END Completed programming of OTP Note 3: VOUT_ MODE is read only for the EM2130 LOCAL CIN VIN PVIN 4X22µF 1206 Load Decoupling EM2130 LOCAL COUT VOUT R1VIN 4X100µF 1206 VINSEN Outpu t Voltage Sense Point R2VIN R1DIV 5V VSENP PVCC R2DIV FB VSENN VCC VCCSEN CTRL SYNC VTRACK VDD33 ADDR0 POK SALERT SDA SCL ADDR1 RTUN E RVSET AGND PGND Figure 16: Recommended Application Circuit Page 36 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Layout Recommendations Recommendation 1: It is highly recommended to use separate nets for AGND and PGND and connecting them through a 0Ω resistor or a short. This method helps with ground management and prevents the noise from the Power Ground disturbing the more sensitive Analog (“Signal”) Ground. Recommendation 2: It is good practice to minimize the PGND loop. Whenever possible the input and output loops should close to the same point, which is the ground of the EM2130 module. Module decoupling ceramic capacitors are to be placed as close as possible to the module in order to contain the switching noise in the smallest possible loops and to improve PVIN decoupling by minimizing the series parasitic inductance of the PVIN traces. For achieving this goal, it helps to place decoupling capacitors on the same side as the module since VIAs are generally more inductive, thus reducing the effectiveness of the decoupling. Of course, bulk and load high frequency decoupling should be placed closer to the load. Figure 17: Top Layer Layout With Critical Components Only Recommendation 3: It is good practice to place the other small components needed by the EM2130 on the opposite side of the board, in order to avoid cutting the power planes on the module side. Since the EM2130 heat is evacuated mostly through the PCB, this will also help with heat dissipation; wide copper planes under the module can also help with cooling. The PVIN copper plane should not be neglected as it helps spread the heat from the high side FET. Recommendation 4: It is recommended that at least below the EM2130 module, the next layers to the surface (2 and n-1) be solid ground planes, which provides shielding and lower the ground impedance at the module level. AGND should be also routed as a copper plane, in order to reduce the ground impedance and reduce noise injection. Page 37 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Figure 18: VIAs in The Power Pads Recommendation 5: In order to better spread the current and the heat through the inner layers, arrays of VIAs should be placed in the power pads. 10mils diameter is a good size for the plated in-pad VIAs. It is critical that through VIAs should not be placed by any means elsewhere under the module; the non-pad area around AGND is VIA keep out area. Recommendation 6: All other signal and LDO decoupling capacitors should be placed as close as possible to the terminal they are decoupling, while the AGND connection should be done through VIAs to the AGND plane. Figure 19: Backside Decoupling All Signal Decoupling Go To The Bottom AGND Plane And Get Connected To The EM2130 Module AGND Through The AGND In-PAD VIAs (Again, No Other VIAs Are Allowed In That Area) Recommendation 7: Figure 20 also shows the 0Ω resistor that connects AGND to PGND. The recommended connecting point, as shown, is to a quiet PGND  the output capacitors PGND. Recommendation 8: Differential remote sense should be routed as much as possible as a differential pair, on an inner layer, preferably shielded by a ground plane. Page 38 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Figure 20: Remote Sense Routing On An Inner Layer (Highlighted, Yellow) Recommendation 9: If the design allows it, stitching VIAs can be used on the power planes, close to the module in order to help with cooling. This is a thermal consideration and does not matter much for the electrical design. Page 39 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Recommended PCB Footprint Figure 21: Recommended PCB Footprint Page 40 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Recommended Solder Stencil Aperture Figure 22: Recommended Solder Stencil Aperture Page 41 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Package Dimensions Figure 23: Package Dimensions Page 42 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Tray Information Figure 24: Tray Information ½ Page 43 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Tray Information (Continued) Figure 25: Tray Information 2/2 Page 44 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Revision History Rev A Date Change(s) 23-Dec-16 Initial Release Page 45 12873 DECEMBER 23, 2016 Rev A Data Sheet | Intel Enpirion Power Solutions: EM2130 Where to Get More Information For more information about Intel and Intel Enpirion PowerSoCs, visit https://www.altera.com/enpirion © 2016 Intel Corporation. All rights reserved. Intel, the Intel logo, Altera, ARRIA, CYCLONE, ENPIRION, MAX, MEGACORE, NIOS, QUARTUS, and STRATIX words and logos are trademarks of Intel Corporation or its subsidiaries in the U.S. and/or other countries. Other marks and brands may be claimed as the property of others. Intel reserves the right to make changes to any products and services at any time without notice. Intel assumes no responsibility or liability arising out of the application or use of any information, product, or service described herein except as expressly agreed to in writing by Intel. Intel customers are advised to obtain the latest version of device specifications before relying on any published information and before placing orders for products or services. * Other marks and brands may be claimed as the property of others. Page 46 12873 DECEMBER 23, 2016 Rev A