OKDL-T/12-W12-xxx-C www.murata-ps.com 12A Digital PoL DC-DC Converter Series Typical unit FEATURES PRODUCT OVERVIEW Small package: 12.2 x 12.2 x 8.0 mm (0.48 x 0.48 x 0.315 in) The OKDL-T/12-W12 is a high efficiency, digital point-of-Load (PoL) DC-DC power converter capable of delivering 12A/60W. Designed for a minimal footprint, the high power-density LGA module measures just 12.2 x 12.2 x 8.0 mm (0.48 x 0.48 x 0.315 in). 0.6 V - 5 V output voltage range High efficiency, typ. 95.4% at 12Vin, 5Vout and 50% load Configuration Control and Monitoring via PMBus™ Adaptive compensation of PWM control loop & fast loop transient response Synchonization input & phase spreading/interleaving Voltage Tracking & Voltage margining MTBF 24 Mh PMBus™ compatibility allows monitoring and confi guration of critical systemlevel performance requirements. Apart from standard PoL performance and safety features like OVP, OCP, OTP, and UVLO, these digital converters have advanced features: Adaptive compensation of PWM control loop, fast loop transient response, synchronization, and phase spreading. These converters are ideal for use in telecommunications, networking, and distributed power applications. For narrow board pitch applications (15 mm/0.6 in) Pre-bias start-up & shut down Monotonic & Soft start Power up Input under voltage shutdown; OTP, output OVP, OCP Remote control & Power Good Applications Distributed power architectures Intermediate bus voltage applications Differential sense pins Servers and storage applications Voltage setting via pin-strap or PMBus™ Advanced Configurable via Graphical User Interface Network equipment ISO 9001/14001 certified supplier Highly automated manufacturing ensures quality PART NUMBER STRUCTURE OKD L - T / 12 - W12 - xxx - C Digital Non-isolated PoL LGA Package Trimmable Output Voltage Range 0.6 - 5Vdc Maximum Rated Output Current in Amps RoHS Hazardous Substance Compliance C = RoHS-6 (does not claim EU RoHS exemption 7b – lead in solder) Software Configuration Digits (001 is positive turn-on logic) (002 is negative turn-on logic)* Input Voltage Range 4.5-14Vdc *Special quantity order is required; contact Murata Power Solutions for MOQ and lead times. PM www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 1 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series ORDERING GUIDE Model Number OKDL-T/12-W12-001-C Output 0.6-5.0 V, 12 A/ 60 W Absolute Maximum Ratings Characteristics TP1 Operating temperature (see Thermal Consideration section) TS Storage temperature VI Input voltage (See Operating Information Section for input and output voltage relations) Logic I/O voltage CTRL, SA0, SA1, SALERT, SCL, SDA, VSET, SYNC, PG, CS_VTRK Ground voltage differential -S, PREF, GND Analog pin voltage VO, +S General and Safety Safety Calculated MTBF Min -40 -40 -0.3 -0.3 -0.3 -0.3 Conditions Designed for UL/IEC/EN 60950 1 Telcordia SR-332, Issue 2 Method 1 Stress in excess of Absolute Maximum Ratings may cause permanent damage. Absolute Maximum Ratings, sometimes referred to as no destruction limits, are normally tested with one parameter at a time exceeding the limits in the Electrical Specification. If exposed to stress above these limits, function and performance may degrade in an unspecified manner. Configuration File This product is designed with a digital control circuit. The control circuit uses a configuration file which determines the functionality and performance of the product. The Electrical Specification table shows parameter values of functionality and performance with the Min Typ Typ 24 Max 120 125 18 4 0.3 5.5 Max Unit °C °C V V V V Unit Mhrs default configuration file, unless otherwise specified. The default configuration file is designed to fit most application needs with focus on high efficiency. If different characteristics are required it is possible to change the configuration file to optimize certain performance characteristics. In this Technical specification examples are included to show the possibilities with digital control. See Operating Information section for information about trade offs when optimizing certain key performance characteristics. VIN VOUT CI CO GND +Sense -Sense CTRL PGOOD SDA SCL Controller and digital interface SA0 SALERT SYNC CS_VTRK VSET SA1 PREF Fundamental Circuit Diagram www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 2 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Electrical Specifications TP1 = -30 to +95°C, VI = 4.5 to 14 V, VI > VO + 1.0 V Typical values given at: TP1 = +25°C, VI = 12.0 V, max IO, unless otherwise specified under Conditions. Default configuration file, 190 10-CDA 102 0370/001. VO defined by pin strap. External CIN = 47 μF ceramic + 270 μF/10 mΩ electrolytic, COUT = 3x100 μF + 0.1 μF ceramic. See Operating Information section for selection of capacitor types. Sense pins are connected to the output pins. Characteristics VI Input voltage Output voltage without pin strap Output voltage adjustment range Output voltage adjustment including PMBus margining Output voltage set-point resolution Output voltage accuracy Internal resistance +S/-S to VOUT/GND +S bias current -S bias current VO Line regulation IO = max IO Load regulation IO = 0 - 100% VOac Output ripple & noise (up to 20 MHz) IO Output current Static input current at max IO Ilim Current limit threshold Isc Short circuit current Efficiency IO = max IO Power dissipation at max IO Pli Input idling power PCTRL Input standby power Typ IO = 0 Max 14 0 0.60 0.50 5.0 5.25 1.2 Including line, load, temp -1 1 47 50 -35 1 2 3 4 7 1 1 1 2 2 10 10 11 19 25 VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V RMS, hiccup mode, VO = 3.3 V, 4 mΩ short 50% of max IO Pd Min 4.5 0 IS Conditions mV mV mVp-p 12 0.7 1.3 2.0 3.5 5.2 15 3 Unit V V V V mV % VO Ω μA μA A A 17 A A VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V 78.8 87.5 90.8 94.1 95.4 81.3 89.0 91.8 94.6 95.8 1.66 1.78 1.93 2.24 2.63 VO = 0.6 V VO = 1.2 V VO = 1.8 V VO = 3.3 V VO = 5.0 V 0.70 0.70 0.71 0.80 0.92 W Turned off with CTRL-pin 0.25 W % % W www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 3 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Characteristics CI Internal input capacitance CO Internal output capacitance COUT Total output capacitance Vtr1 Load transient peak voltage deviation ttr1 Load transient recovery time Conditions VI = 0 V VO = 0 V VO = 3.3 V VO = 5.0 V Effective capacitance Note 1 Min Switching frequency range Switching frequency set-point accuracy External Sync Duty Cycle Input Clock Frequency Drift Tolerance Threshold, VUVLO Input Under Voltage Lockout (hardware controlled) Hysteresis Input Over Voltage Lockout (hardware controlled) Threshold, VOVLO Load step 25-75-25% of max IO, di/dt = 1.5 A/μs CO=3x100 μF + 270 μF VO = 3.3 V PMBus configurable FREQUENCY_SWITCH Note 2 External clock source -10 40 -10 Rising edge 3.8 Input rising Threshold range Threshold range Input Under/Over Voltage Protection, IUVP/ IOVP UVP threshold range Fault response OCP threshold Over Current Protection, OCP Over Temperature Protection, OTP Over Temperature Shutdown (hardware controlled) OCP threshold range kHz 300-1000 kHz ±5 4.1 10 60 10 % % % 4.4 V 15.2 V 16 V 0-14.7 V 4.1 V PMBus configurable VIN_UV_FAULT_LIMIT 0-14.7 V 14.4 V PMBus configurable VIN_OV_FAULT_LIMIT 0-14.7 V VIN_UV_FAULT_RESPONSE VIN_OV_FAULT_RESPONSE PMBus configurable VOUT_UV_FAULT_LIMIT PMBus configurable VOUT_OV_FAULT_LIMIT VOUT_UV_FAULT_RESPONSE VOUT_OV_FAULT_RESPONSE Set value PMBus configurable IOUT_OC_FAULT_LIMIT Fault response IOUT_OC_FAULT_RESPONSE OTP threshold OTP hysteresis Note 4 PMBus configurable OT_FAULT_LIMIT PMBus configurable Fault response OT_FAULT_RESPONSE Threshold Hysteresis Accuracy Note 4 OTP threshold range 600 V PMBus configurable VIN_OFF OVP threshold OVP threshold range μs V UVP threshold Output voltage Over/Under Voltage Protection, OVP/UVP 25 3.8 Set point accuracy Fault response mV 0-14.7 IOVP threshold IOVP threshold range 60 V IUVP threshold IUVP threshold range μF 4.35 PMBus configurable VIN_ON Threshold Input Turn-Off Voltage 14.3 Unit μF μF 0.24 Threshold Input Turn-On Voltage Max 55 Switching frequency Fsw Typ 47 47 24 15 -150 150 Shutdown, make continuous restarts at 700 ms interval (hiccup). Note 3 85 mV % VO 0-100 % VO 115 % VO 100-115 % VO Shutdown, make continuous restarts at 700 ms interval (hiccup). Note 3 16 0-18 Shutdown, make continuous restarts at 700 ms interval (hiccup). Note 3. 120 -40…+120 15 Shutdown, make continuous restarts at 700 ms interval (hiccup). Note 3 150 20 ±20 A A °C °C °C °C °C °C www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 4 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Characteristics VOL Logic output low signal level VOH Logic output high signal level IOL IOH VIL VIH IIL_CTRL II_LEAK fSMB Logic output low sink current Logic output high source current Logic input low threshold Logic input high threshold Logic input low sink current Logic leakage current SMBus Operating frequency TBUF SMBus Bus free time tset thold SMBus SDA setup time from SCL SMBus SDA hold time from SCL SMBus START/STOP condition setup/hold time from SCL SCL low period SCL high period Tlow Thigh Initialization time Conditions Min SCL, SDA, SYNC, SALERT, PG Sink/source current = 4 mA 2.8 SCL, SDA, CTRL, SYNC 4 4 0.8 2 CTRL SCL, SDA, SYNC, SALERT, PG 0.5 10 400 STOP bit to START bit See section SMBus – Timing Note 5 Delay accuracy 100 300 600 1.3 0.6 ns ns ns μs μs PMBus configurable TON_DELAY TON_DELAY value sent versus readback Actual delay duration versus TON_DELAY read-back Note 5 Ramp duration range Ramp set resolution Ramp set accuracy Ramp time accuracy PMBus configurable TON_RISE Varies with VO TON_RISE value sent versus read-back Actual ramp duration versus TON_RISE read-back Signal level PG threshold PG thresholds range (Non-tracking only) Power Good , PG 1-145 ms 0.6 ms ±0.5 x Delay set resolution ms ms ms 1 - (255 x Ramp set resolution) ms 0.4 1 ±0.5 x Ramp set resolution VO = 0.6 V VO = 1.2 – 3.3 V VO = 5.0 V Rising Falling Tracking mode See section Voltage Tracking PMBus configurable POWER_GOOD_ON POWER_GOOD_OFF ms ms 10 Signal duration Compensation Calibration 23 10 ±0.8 Ramp duration Soft-start Rise Time (0-100% of VO) mA mA V V mA uA kHz μs Delay set resolution Delay set accuracy Unit V 1.3 From VI > VUVLO to ready to be enabled Delay duration range Max 0.4 V Delay duration Soft-start On Delay Time Typ ms ms ±10 μs 5 3.5 2.5 2 ms % VO 90 85 % VO % VO 450 mV 0 100 % VO PG delay From VO reaching target to PG assertion 11 ms Enabled compensation calibration (default) Tracking mode See section Voltage Tracking 20 ms PG delay From VO reaching PG rising threshold to PG assertion 0 ms Tracking mode See section Voltage Tracking 20 ms Disabled compensation calibration Tracking Input Voltage Range Tracking Accuracy CS_VTRK pin Note 6 0 1.2 V -100 100 mV www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 5 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Characteristics Conditions Min Input voltage READ_VIN Output voltage READ_VOUT Monitoring accuracy Output current READ_IOUT Note 7 TP1 = 0-95°C, VI = 4.5-14 V, IO > 5 A TP1 = 0-95°C, VI = 4.5-14 V, IO < 5 A Temperature READ_ TEMPERATURE_1 Note 4 -5 Duty cycle < 10% -3 Duty cycle > 10% -1 Duty cycle READ_DUTY_CYCLE Note 1. Value refers to total (internal + external) effective output capacitance. Capacitance derating with VO typical for ceramic capacitors (bias characteristics) and temperature variations must be considered for the external capacitor(s). See section External Output Capacitors. Note 2. A switching frequency close to 475 kHz should not be used since this frequency represents a boundary of two operational modes of the product. There are configuration changes to consider when changing the switching frequency, see section Switching Frequency. Note 3.The restart interval is configurable between 100ms and 700ms in 100ms steps. Severe overcurrent faults occurring with VO > 2.5V may result in a restart interval of 1200 ms instead of the configured value. See operating conditions for other fault response alternatives. Typ Max Unit ±3 % VI ±1 % VO ±8.5 % IO ±0.4 A ±0.5 5 °C 3 % 1 % Note 4. Temperature measured internally at temperature position P3. See section Over Temperature Protection. Note 5. Same specification applies for soft-stop and TOFF_DELAY/TOFF_FALL if enabled. The internal ramp and delay generators can only achieve certain discrete timing values. A written TON/OFF_DELAY or TON/OFF_RISE value will be rounded to the closest achievable value, thus a command read-back provides the actual set value. See section Soft-Start and Soft-Stop. Note 6.Larger tracking input range is provided by external resistor divider, see section Voltage Tracking. Note 7. At VO > 3.5V and VO / VI in the approximate range 55-70% there may be an additional current monitoring inaccuracy on the negative side up to -1 A. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 6 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Typical Characteristics, VO = 0.6 V Default Configuration, TP1 = +25°C Efficiency Power Dissipation [%] [W] 90 2.5 85 80 VI 75 4.5 V 70 2.0 VI 4.5 V 1.5 5V 5V 1.0 65 12 V 12 V 60 14 V 14 V 0.5 55 50 0 2 4 6 8 10 12 0.0 0 [A] 2 4 6 8 10 Efficiency vs. load current and input voltage. Dissipated power vs. load current and input voltage. Output Current Derating Current Limit Characteristics [A] 12 [A] [V] 12 0.75 10 3.0 m/s 8 2.0 m/s 6 1.0 m/s 0.5 m/s 4 Nat. Conv. 2 0.60 VI 0.45 4.5 V 5V 0.30 12 V 14 V 0.15 0.00 0 85 90 95 100 105 [°C] 12 13 14 15 16 17 [A] Available load current vs. ambient air temperature and airflow at VI = 12 V. See section Thermal Consideration. Output voltage vs. load current and input voltage. Output Ripple and Noise Transient Response Fundamental output voltage ripple at VI = 12 V, CO = 3x100 μF, IO = 12 A. Scale: 5 mV/div, 1 μs/div, 20 MHz bandwidth. See section Output Ripple and Noise. Output voltage response to load current step change (3–9–3 A) at VI = 12 V, CO = 3x100 μF + 270 μF/10m. Default compensation settings. Scale: 50 mV/div, 5 A/div, 50 μs/div. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 7 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Typical Characteristics, VO = 1.2 V Default Configuration, TP1 = +25°C Efficiency Power Dissipation [%] [W] 95 2.5 90 2.0 85 VI VI 80 4.5 V 1.5 4.5 V 75 5V 5V 1.0 70 12 V 12 V 65 14 V 14 V 0.5 60 55 0.0 0 2 4 6 8 10 12 0 [A] 2 4 6 8 10 Efficiency vs. load current and input voltage. Dissipated power vs. load current and input voltage. Output Current Derating Current Limit Characteristics [A] 12 [A] [V] 12 1.50 10 3.0 m/s 8 2.0 m/s 6 1.0 m/s VI 1.20 4.5 V 0.90 0.5 m/s 4 5V 0.60 12 V Nat. Conv. 14 V 0.30 2 0 85 90 95 100 105 0.00 [°C] 12 13 14 15 16 17 [A] Available load current vs. ambient air temperature and airflow at VI = 12 V. See section Thermal Consideration. Output voltage vs. load current and input voltage. Output Ripple and Noise Transient Response Fundamental output voltage ripple at VI = 12 V, CO = 3x100 μF, IO = 12 A. Scale: 5 mV/div, 1 μs/div, 20 MHz bandwidth. See section Output Ripple and Noise. Output voltage response to load current step change (3–9–3 A) at VI = 12 V, CO = 3x100 μF + 270 μF/10m. Default compensation settings. Scale: 50 mV/div, 5 A/div, 50 μs/div. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 8 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Typical Characteristics, VO = 1.8 V Default Configuration, TP1 = +25°C Efficiency Power Dissipation [%] [W] 100 2.5 95 2.0 90 VI VI 85 4.5 V 1.5 4.5 V 80 5V 5V 75 1.0 12 V 70 14 V 12 V 14 V 0.5 65 60 0 2 4 6 8 10 12 0.0 0 [A] 2 4 6 8 10 Efficiency vs. load current and input voltage. Dissipated power vs. load current and input voltage. Output Current Derating Current Limit Characteristics [A] 12 [A] [V] 12 2.0 10 3.0 m/s 8 2.0 m/s 6 1.0 m/s 0.5 m/s 4 Nat. Conv. VI 1.6 4.5 V 1.2 5V 0.8 12 V 14 V 0.4 2 0.0 0 85 90 95 100 105 12 13 14 15 16 [°C] 17 [A] Available load current vs. ambient air temperature and airflow at VI = 12 V. See section Thermal Consideration. Output voltage vs. load current and input voltage. Output Ripple and Noise Transient Response Fundamental output voltage ripple at VI = 12 V, CO = 3x100 μF, IO = 12 A. Scale: 5 mV/div, 1 μs/div, 20 MHz bandwidth. See section Output Ripple and Noise. Output voltage response to load current step change (3–9–3 A) at VI = 12 V, CO = 3x100 μF + 270 μF/10m. Default compensation settings. Scale: 50 mV/div, 5 A/div, 50 μs/div. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 9 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Typical Characteristics, VO = 3.3 V Default Configuration, TP1 = +25°C Efficiency Power Dissipation [%] [W] 100 2.5 95 2.0 VI VI 90 4.5 V 85 1.5 4.5 V 5V 5V 1.0 12 V 12 V 80 14 V 75 70 14 V 0.5 0.0 0 2 4 6 8 10 12 0 [A] 2 4 6 8 10 Efficiency vs. load current and input voltage. Dissipated power vs. load current and input voltage. Output Current Derating Current Limit Characteristics [A] 12 [A] [V] 12 3.6 10 3.0 m/s 3.0 8 2.0 m/s 2.4 6 1.0 m/s 1.8 0.5 m/s 4 VI 4.5 V 5V 12 V 1.2 Nat. Conv. 14 V 0.6 2 0.0 0 85 90 95 100 105 [°C] 12 13 14 15 16 17 [A] Available load current vs. ambient air temperature and airflow at VI = 12 V. See section Thermal Consideration. Output voltage vs. load current and input voltage. Output Ripple and Noise Transient Response Fundamental output voltage ripple at VI = 12 V, CO = 3x100 μF, IO = 12 A. Scale: 5 mV/div, 1 μs/div, 20 MHz bandwidth. See section Output Ripple and Noise. Output voltage response to load current step change (3–9–3 A) at VI = 12 V, CO = 3x100 μF + 270 μF/10m. Default compensation settings. Scale: 50 mV/div, 5 A/div, 50 μs/div. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 10 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Typical Characteristics, VO = 5.0 V Default Configuration, TP1 = +25°C Efficiency Power Dissipation [W] [%] 100 3.5 3.0 95 VI 90 6V 85 9.6 V 80 12 V 14 V 75 VI 2.5 6V 2.0 9.6 V 1.5 12 V 1.0 14 V 0.5 70 0 2 4 6 8 10 0.0 12 [A] 0 2 4 6 8 10 Efficiency vs. load current and input voltage. Dissipated power vs. load current and input voltage. Output Current Derating Current Limit Characteristics [A] 12 [A] [V] 12 6.0 10 3.0 m/s 8 2.0 m/s 6 1.0 m/s 5.0 VI 4.0 6V 3.0 9.6 V 0.5 m/s 4 12 V 2.0 Nat. Conv. 2 14 V 1.0 0 80 85 90 95 100 0.0 [°C] 12 13 14 15 16 17 [A] Available load current vs. ambient air temperature and airflow at VI = 12 V. See section Thermal Consideration. Output voltage vs. load current and input voltage. Output Ripple and Noise Transient Response Fundamental output voltage ripple at VI = 12 V, CO = 3x100 μF, IO = 12 A. Scale: 5 mV/div, 1 μs/div, 20 MHz bandwidth. See section Output Ripple and Noise. Output voltage response to load current step change (3–9–3 A) at VI = 12 V, CO = 3x100 μF + 270 μF/10m. Default compensation settings. Scale: 50 mV/div, 5 A/div, 50 μs/div. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 11 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Typical Characteristics Default Configuration, TP1 = +25°C, VO = 3.3 V Start-up by input source Shut-down by input source VI VI VO VO PG PG Start-up enabled by applying VI. TON_DELAY = TON_RISE = 10 ms (default). VI = 12 V, IO = max IO, PG pulled up to VO. Scale: 10 or 2 V/div, 10 ms/div. Shut-down by removing VI. VI = 12 V, IO = max IO, PG pulled up to VO. Scale: 10 or 2 V/div, 1 ms/div. Start-up by CTRL signal Shutdown by CTRL signal CTRL CTRL VO VO PG PG Start-up enabled by CTRL signal. TON_DELAY = TON_RISE = 10 ms (default). VI = 12 V, IO = max IO, PG pulled up to VO. Scale: 2 V/div, 10 ms/div. Shut-down by CTRL signal. VI = 12 V, IO = max IO, PG pulled up to VO. Scale: 2 V/div, 1 ms/div. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 12 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Conducted EMI Input terminal value (typical for default configuration) Output Ripple and Noise Output ripple and noise is measured according to figure below. A 50 mm conductor works as a small inductor forming together with the two capacitances a damped filter. 50 mm conductor Vout S co Tantalum Capacitor 10 μF Ceramic Capacitor 0.1 μF Load EMC Specification Conducted EMI is measured according to the test set-up below. The fundamental switching frequency is 600 kHz. S GND 50 mm conductor BNC-contact to oscilloscope Output ripple and noise test set-up EMI without filter To spectrum analyzer RF Current probe 1kHz – 50MHz Battery supply The digital compensation of the product is designed to automatically provide stability, accurate line and load regulation and good transient performance for a wide range of operating conditions (switching frequency, input voltage, output voltage, output capacitance). Inherent from the implementation and normal to the product there will be some low-frequency noise or wander at the output, in addition to the fundamental switching frequency output ripple. The total output ripple and noise is maintained at a low level. Resistive load DUT C1 50mm C1 = 10uF / 600VDC Feed- Thru RF capacitor 800mm 200mm VI=12 V, VO=3.3 V, IO=12 A, CO=3x100 μF,10 mV/div, 50 μs/div Test set-up conducted emission, power lead Example of low frequency noise at the output Layout Recommendations The radiated EMI performance of the product will depend on the PWB layout and ground layer design. It is also important to consider the standoff of the product. If a ground layer is used, it should be connected to the output of the product and the equipment ground or chassis. A ground layer will increase the stray capacitance in the PWB and improve the high frequency EMC performance. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 13 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Operating information Power Management Overview This product is equipped with a PMBus™ interface. The product incorporates a wide range of readable and configurable power management features that are simple to implement with a minimum of external components. Additionally, the product includes protection features that continuously safeguard the load from damage due to unexpected system faults. A fault is also shown as an alert on the SALERT pin. The product is delivered with a default configuration suitable for a wide range of operation in terms of input voltage, output voltage, and load. The configuration is stored in an internal Non-Volatile Memory (NVM). All power management functions can be reconfigured using the PMBus™ interface. Please contact your local Murata Power Solutions representative for design support of custom configurations or appropriate SW tools for design and download of your own configurations. Input Under Voltage Lockout, UVLO The product provides a non-configurable under voltage lockout (UVLO) circuit that monitors the internal supply of the converter. Below a certain input voltage level the internal supply will be too low for proper operation and the product will be in under voltage lockout, not switching or responding to the CTRL pin or to PMBus™ commands. Input Over Voltage Lockout, OVLO The product provides a non-configurable over voltage lockout (OVLO) circuit that will shut down the product when the input voltage rises above a certain level. The product will not switch, respond to the CTRL pin or to PMBus™ commands when being in over voltage lockout. Input Turn-On and Turn-Off Voltage The product monitors the input voltage and will turn-on and turn-off the output at configured levels (assuming the product is enabled by CTRL pin or PMBus™). The default turn-on input voltage level is 4.35 V whereas the corresponding turn-off input voltage level is 3.8 V. The turn-on and turn-off levels may be reconfigured using the PMBus™ commands VIN_ON and VIN_OFF. Input Under Voltage Protection (IUVP) The product monitors the input voltage continously and will respond as configured when the input voltage falls below the configured threshold level. The product can respond in a number of ways as follows: 1. Continue operating without interruption. 2. Continue operating for a given delay period, followed by an output voltage shutdown if the fault still exists. 3. Immediate and definite shutdown of output voltage until the fault is cleared by PMBus™ or the output voltage is re-enabled. 4. Immediate shutdown of output voltage while the fault is present. Operation resumes and the output is enabled when the fault condition no longer exists. The default response is 4. The IUVP function can be reconfigured using the PMBus™ commands VIN_UV_FAULT_LIMIT and VIN_UV_FAULT_RESPONSE. Input Over Voltage Protection (IOVP) The product monitors the input voltage continously and will respond as configured when the input voltage rises above the configured threshold level. Refer to section “Input Under Voltage Protection” for response configuration options and default setting. Input and Output Impedance The impedance of both the input source and the load will interact with the impedance of the product. It is important that the input source has low characteristic impedance. If the input voltage source contains significant inductance, the addition of a capacitor with low ESR at the input of the product will ensure stable operation. External Input Capacitors The input ripple RMS current in a buck converter can be estimated to Eq. 1. IinputRMS I load D 1 D , where I load is the output load current and Dis the duty cycle. The maxi mum load ripple current becomes I load 2. The ripple current is divided into three parts, i.e., currents in the input source, external input capacitor, and internal input capacitor. How the current is divided depends on the impedance of the input source, ESR and capacitance values in the capacitors. For most applications non-tantalum capacitors are preferred due to the robustness of such capacitors to accommodate high inrush currents of systems being powered from very low impedance sources. It is recommended to use a combination of ceramic capacitors and low-ESR electrolytic/polymer bulk capacitors. The low ESR of ceramic capacitors effectively limits the input ripple voltage level, while the bulk capacitance minimizes deviations in the input voltage at large load transients. It is recommended to use at least 47 uF of ceramic input capacitance. At duty cycles between 25% and 75% where the input ripple current increases (see Eq. 1), additional ceramic capacitance will help to keep the input ripple voltage low. The required bulk capacitance depends on the impedance of the input source and the load transient levels at the output. In general a low-ESR bulk capacitor of at least 100 uF is recommended. The larger the duty cycle is, the larger impact an output load step will have on the input side, thus the larger bulk capacitance is required to limit the input voltage deviation. If several products are connected in a phase spreading setup the amount of input capacitance per product can be reduced. Input Capacitors must be placed closely and with low impedance connections to the VIN and GND pins in order to be effective. External Output Capacitors The output capacitor requirement depends on two considerations; output ripple voltage and load transient response. To achieve low www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 14 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series It is recommended to locate low ESR ceramic and low ESR electrolytic/polymer capacitors as close to the load as possible, using several capacitors in parallel to lower the effective ESR. It is important to use low resistance and low inductance PCB layouts and cabling in order for capacitance to be effective. The control loop of the product is optimized to operate with lowESR output capacitors and is capable of achieving a fast loop transient response with a reduced amount of capacitance. The effective output capacitance is recommended to be in the range [COUT_low, COUT_ high] according to equations Eq. 2 and Eq. 3 below, where FSW is the switching frequency. The compensation implementation of the product is optimized for this range. Eq. 2. C OUT _ low Eq. 3. C OUT _ high In cases where the external output filter includes an inductor (forming a pi filter) according to the picture below, the following must be considered. Vout S OKDL CO LEXT CEXT S GND FSW 2 In order for the compensation calibration (see next sections) to give a reliable result, the following condition should be fulfilled: 16 10 7 FSW FLC _ EXT 2 Permissible Recommended UNSTABLE [kHz] 10 700 2S LEXT CEXT ! FSW 10 If this condition is not fulfilled it is recommended to disable compensation calibration and set FLC manually in COMP_MODEL (see next sections). Please contact your Murata Power Solutions sales representative for further support. 100 600 1 where FLC_EXT is the resonance frequency of the external filter and FSW is the switching frequency. If there are multiple pi filters in parallel on the output, giving a more complex transfer function with several resonance peaks, each of the peaks should be above FSW/10. 1000 500 Note also that Eq. 2 and Eq. 3 and the chart refers to the effective capacitance, not taking into account the capacitance derating that applies for ceramic capacitors with increased voltage or temperature variations. External output filter with inductor (pi filter). [ȝF] 400 Note that Eq. 2 and Eq. 3 and the chart above refer to the total capacitance at the output, thus including both the capacitance internal to the product and the external capacitance applied in the application. The internal output capacitance is listed in the Electrical Characteristics table. 2.6 10 7 10000 300 capacitance is required. The limit of COUT_low must be followed in order to guarantee stability. Load ripple voltage, the output capacitor bank must have a low ESR value, which is achieved with ceramic output capacitors. A small output voltage deviation during load transients is achieved by using a larger amount of capacitance. Designs with smaller load transients can use fewer capacitors and designs with more dynamic load content will require more load capacitors to achieve a small output deviation. Improved transient response can also be achieved by adjusting the settings of the control loop of the product (see section Compensation Implementation). 800 900 For the OKDL products, it is recommended that the remote sense connections are made at a point before the external inductor, as illustrated in the drawing above. 1000 Effective total output capacitance limits vs switching frequency. The product permits a large range of output capacitance, thus capacitance above COUT_high is acceptable. This capability is important in applications where the output capacitance may be unknown or not well controlled or in applications where a large amount of output Dynamic Loop Compensation (DLC) The typical design of regulated power converters includes a control function with a feedback loop that can be closed using either analog or digital circuits. The feedback loop is required to provide a stable output voltage, but should be optimized for the output filter to maintain output voltage regulation during transient conditions such as sudden changes in output current and/or input voltage. Digitally controlled converters allow one to optimize loop parameters without the need to change components on the board, however, optimization www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 15 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series can still be challenging because the key parameters of the output filter include parasitic impedances in the PCB and the often distributed filter components themselves. Dynamic Loop Compensation has been developed to solve the problem of compensation for a converter with a difficult to define output filter. This task is achieved by utilization of algorithms that can characterize an arbitrary output filter based on behavior of the output voltage in response to a disturbance initiated by the algorithm, or occurring due to the changes in operating conditions, and automatically adjust feedback loop parameters to match the output filter. Details of the algorithm that is used to characterize an output filter and the different operational modes can be found in the following sections. user. Note however, as soon as the output voltage is disabled, the FLC value in COMP_MODEL will revert back to the corresponding value stored in User NVM. Therefore, user values of COMP_MODEL should be written to NVM, or, if written to RAM only, be written before each time the output voltage is enabled. COMP_MODEL should only be changed in RAM while the output voltage is disabled. By setting bit 2 in ADAPTIVE_MODE a STORE_USER_ALL command will automatically be performed after the next calibration, effectively storing the measured FLC value in COMP_MODEL 15:0 in NVM as the FLC value for subsequent ramp-ups. Output Voltage Compensation calibration Compensation Implementation Unlike PID-based digital power regulators the product uses a statespace model based algorithm that is valid for both the small- and large-signal response and accounts for duty-cycle saturation effects. This eliminates the need for users to determine and set thresholds for transitioning from linear to nonlinear modes. These capabilities result in fast loop transient response and the possibility of reducing the number of output capacitors. Compensation calibration is when the resonance frequency FLC of the output stage is measured. The FLC value is used to automatically control the compensation. During ramp-up of the output voltage, robust and low bandwidth default compensation settings are used based on the default FLC value assigned by bits 15:0 in PMBus™ command COMP_MODEL. If the switching frequency is changed the default FLC should be adjusted according to Eq. 4 to maintain robust settings. Eq. 4. FLC _ DEFAULT FSW 32 It is possible for the user to write any FLC value in COMP_MODEL to be used during ramp-up. This is useful in cases where improved dynamic performance is needed during ramp-up. User assignment of FLC in COMP_MODEL is also needed when calibration is disabled, since in such case the FLC value used during ramp-up will continue to be used when ramp-up has finished. When calibration is enabled (default), an AC low amplitude measurement signal is applied on the output immediately after ramp-up has finished. See Electrical Characteristics table for a specification of this measurement signal. During calibration the resonant frequency FLC of the power stage is measured. From the result an internal nonlinear model is constructed to optimize the bandwidth and transient response of the product. Pole locations of the closed system are automatically selected based on switching frequency, measured FLC and the output voltage level. After each performed calibration, bits 15:0 in COMP_MODEL are updated with measured FLC, thus this value can be read out by the Time The table below shows an example of improvement in transient response due to the compensation calibration, compared to using the FLC_DEFAULT value. Voltage deviation Recovery time Non-calibrated compensation 53 mV 50 μs Calibrated compensation 34 mV 30 μs Load transient performance non-calibrated compensation with FLC_DEFAULT vs. calibrated compensation. VI=12 V, VO=1.2 V, CO = 3x100 μF + 270μF/10mΩ, load step 3-9-3 A, 1 A/us. The PMBus™ command ADAPTIVE_MODE provides the user different options for compensation calibration: 1. Calibration is performed once after each ramp-up (default). (ADAPTIVE_MODE = 0x024B). 2. Calibration is performed once after first ramp-up after input voltage is applied (ADAPTIVE_MODE = 0x124B). 3. Calibration is performed continuously after ramp-up at ~800 ms interval (ADAPTIVE_MODE = 0x034B). 4. Calibration is disabled (ADAPTIVE_MODE = 0x004B). The FLC value stored in bits 15:0 in COMP_MODEL will be applied. 5. Calibration is performed continuously in response to a PMBus™ command. Controlled by setting/clearing bit 8 in ADAPTIVE_MODE during operation. Compensation may be set more or less aggressive by adjusting the feedback gain factor, controlled by the PMBus™ command FEEDBACK_EFFORT. This parameter is proportional to the open loop gain of the system. Increasing the gain, i.e the control effort, will reduce the voltage deviation at load transients, at the expense of somewhat increased jitter and noise on the output. Users also have access to www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 16 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series the PMBus™ command ZETAP, which corresponds to the damping ratio of the closed loop system. By default the product uses 0.5 as the feedback gain factor and 1.5 for damping ratio, to target a system bandwidth of 10% of the switching frequency. Disabled In some operating conditions at low output voltages, it is possible to enhance the recovery time at load release by enabling Negative Duty Cycle by PMBus™ command LOOP_CONFIG. Enabled The graphs below exemplify the impact on load transient performance when adjusting the feedback gain factor, the damping ratio and the Negative Duty Cycle feature. [mV] V I =12 V, V O =0.6 V, C O = 3x100 μF + 270μF/10m, load step 3-9-3 A,1 A/us. FEEDBACK_EFFORT = 0.8, ZETAP = 1.5. Scale: 20 mV/div, 5 A/div, 10 μs/div. 70 60 Load release response at enabled/disabled Negative Duty Cycle at low output voltage. 50 40 30 20 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 FEEDBACK_EFFORT CO=3x100μF CO=3x100μF+270μF/10m V I =12 V, V O =1.2 V, load step 3-9-3 A,1 A/us. Remote Sense The product has remote sense that can be used to compensate for voltage drops between the output and the point of load. The sense traces should be located close to the PWB ground layer to reduce noise susceptibility. Due to derating of internal output capacitance the voltage drop should be kept below VDROPMAX = (5.25 – VOUT) / 2. A large voltage drop will impact the electrical performance of the regulator. If the remote sense is not needed +S must be connected to VOUT and −S must be connected to GND. Output Voltage Control Voltage deviation vs. FEEDBACK_EFFORT setting. To control the output voltage the product features both a remote control input through the CTRL pin and a PMBus™ enable function by the command OPERATION. It is also possible to configure the output to be always on. [us] 30.0 By default the output is controlled by the CTRL pin only. The output voltage control can be reconfigured using the PMBus™ command ON_OFF_CONFIG. 27.0 24.0 Remote Control 21.0 Vext 18.0 15.0 1.8 1.7 1.6 1.5 1.4 1.3 1.2 1.1 1.0 CTRL ZETAP V I =12 V, V O =1.2 V, C O = 3x100 μF + 270μF/10m, load step 3-9-3 A,1 A/us. Recovery time to within 1% of VO vs. ZETAP setting. GND The product is equipped with a remote control function, i.e., the CTRL pin. The remote control can be connected to either the primary negative input connection (GND) or an external voltage (Vext). See Absolute Maximum Rating for maximum voltage level allowed at the CTRL pin. The CTRL function allows the product to be turned on/off by an external device like a semiconductor or mechanical switch. The CTRL pin has an internal 6.8 kΩ pull-up resistor to 3.3 V. The external device must provide a minimum required sink current to guarantee a voltage not higher than the logic low threshold level (see www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 17 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Electrical Characteristics). When the CTRL pin is left open, the voltage generated on the CTRL pin is 3.3 V. By default the product provides “positive logic” RC and will turn on when the CTRL pin is left open and turn off when the CTRL pin is applied to GND. It is possible to configure “negative logic” instead by using the PMBus™ command ON_OFF_CONFIG. If the device is to be synchronized to an external clock source, the clock frequency must be stable prior to asserting the CTRL pin. Output Voltage Adjust using Pin-strap Resistor Using an external Pin-strap resistor, RSET, the output voltage can VSET be set in the range 0.6 V to 5.0 V at 16 different levels shown R SET in the table below. The resistor PREF should be applied between the VSET pin and the PREF pin. RSET also sets the maximum output voltage; see section “Output Voltage Range Limitation”. The resistor is sensed only at the application of input voltage. Changing the resistor value during normal operation will not change the output voltage. The input voltage must be at least 1 V larger than the output voltage in order to deliver the correct output voltage. See Ordering Information for output voltage range. The following table shows recommended resistor values for RSET. Maximum 1% tolerance resistors are required. VOUT [V] RSET[kΩ] VOUT [V] RSET[kΩ] 0.60 5.11 1.05 17.8 0.70 6.19 1.10 21.5 0.75 7.15 1.20 26.1 0.80 8.25 1.50 31.6 0.85 9.53 1.80 38.3 0.90 11.0 2.50 44.2 0.95 12.7 3.30 51.1 1.00 14.7 5.00 59.0 Output Voltage Adjust using PMBus™ The output voltage set by pin-strap can be overridden using the PMBus™ command VOUT_COMMAND. See Electrical Specification for adjustment range. Voltage Margining Up/Down Using the PMBus™ interface it is possible to adjust the output higher or lower than its nominal voltage setting in order to determine whether the load device is capable of operating over its specified supply voltage range. This provides a convenient method for dynamically testing the operation of the load circuit over its supply margin or range. It can also be used to verify the function of supply voltage supervisors. Margin limits of the nominal output voltage ±5% are default, but the margin limits can be reconfigured using the PMBus™ commands VOUT_MARGIN_LOW, VOUT_MARGIN_HIGH. Margining is activated by the command OPERATION. Output Voltage Trim The actual output voltage can be trimmed to optimize performance of a specific load by setting a non-zero value for PMBus™ command VOUT_TRIM. The value of VOUT_TRIM is summed with VOUT_COMMAND, allowing for multiple products to be commanded to a common nominal value, but with slight adjustments per load. Output Voltage Range Limitation The output voltage is by default limited to the least of 5.5 V or 110% of the nominal output voltage, where the nominal output voltage is defined by pin-strap or by VOUT_COMMAND in Non-Volatile Memory (see section Initialization Procedure). This protects the load from an over voltage due to an accidentally written wrong VOUT_COMMAND. The limitation applies to the regulated output voltage, rather than the internal value of VOUT_COMMAND. The output voltage limit can be reconfigured using the PMBus™ command VOUT_MAX. Output Over Voltage Protection (OVP) The product includes over voltage limiting circuitry for protection of the load. The default OVP limit is 15% above the nominal output voltage. The product can be configured to respond in different ways to the output voltage exceeding the OVP limit: 1. Continue operating without interruption. 2. Continue operating for a given delay period, followed by an output voltage shutdown if the fault still exists. 3. Immediate and definite shutdown of output voltage until the fault is cleared by PMBus™ or the output voltage is re-enabled. 4. Immediate shutdown of output voltage while the fault is present. Operation resumes and the output is enabled when the fault condition no longer exists. The default response is 4. The OVP limit and fault response can be reconfigured using the PMBus™ commands VOUT_OV_FAULT_LIMIT and VOUT_OV_FAULT_RESPONSE. Output Under Voltage Protection (UVP) The product includes output under voltage limiting circuitry for protection of the load. The default UVP limit is 15% below the nominal output voltage. Refer to section “Output Over Voltage Protection” for response configuration options and default setting. Power Good PG (Power Good) is an active high open drain output used to indicate when the product is ready to provide regulated output voltage to the load. During startup and during a fault condition, PG is held low. By default, PG is asserted high after the output has ramped to a voltage above 90% of the nominal voltage and a successful compensation calibration has completed. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 18 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series By default, PG is deasserted if the output voltage falls below 85% of the nominal voltage. These limits may be changed using the PMBus™ commands POWER_GOOD_ON and POWER_GOOD_OFF. FREQUENCY_SWITCH must be set to a value close to the frequency of the external clock prior to enabling the output voltage, in order to set the internal controller in proper operational mode. The PG output is not defined during ramp up of the input voltage due to the initialization of the product. The product automatically checks for a clock signal on the SYNC pin when input power is applied and when the output is enabled. If no incoming clock signal is present, the product will use the internal oscillator at the configued switching frequency. Over Current Protection (OCP) The product includes robust current limiting circuitry for protection at continuous overload. After ramp-up is complete the product can detect an output overload/short condition. The following OCP response options are available: 1. Continue operating without interruption (this could result in permanent damage to the product). 2. Immediate and definite shutdown of output voltage until the fault is cleared by PMBus™ or the output voltage is re-enabled. 3. Immediate shutdown of output voltage followed by continous restart attempts of the output voltage with a preset interval (“hiccup” mode). The default response from an over current fault is 3. Note that delayed shutdown is not supported. The load distribution should be designed for the maximum output short circuit current specified. The OCP limit and response can be reconfigured using the PMBus™ commands IOUT_OC_FAULT_LIMIT and IOUT_OC_FAULT_RESPONSE. If option 2 above is to be used, the TON_MAX_FAULT_RESPONSE setting should match the setting of IOUT_OC_FAULT_RESPONSE in order to make sure that no restart attempts occur. Switching Frequency The default switching frequency yields optimal performance. The switching frequency can be re-configured in a certain range using the PMBus™ command FREQUENCY_SWITCH. Refer to Electrical Specification for default switching frequency and range. If changing the switching frequency more than +/-10% from the default value, the following should be considered to maintain reliable operation: The default FLC value in COMP_MODEL should be adjusted, see section Compensation Implementation. Adjustment of the fixedDTR and fixedDTF values in DEADTIME_GCTRL may be required, for higher switching frequencies in particular. Changing the switching frequency will affect efficiency/power dissipation, load transient response and output ripple. Synchronization The product may be synchronized with an external clock to eliminate beat noise on the input and output voltage lines by connecting the clock source to the SYNC pin. Synchronization can also be utilized for phase spreading, described in section Phase Spreading. In the event of a loss of the external clock signal during normal operation, the product will automatically switch to the internal oscillator and switch at a frequency close to the original SYNC input frequency. Phase Spreading When multiple products share a common DC input supply, spreading of the switching clock phase between the products can be utilized. This dramatically reduces input capacitance requirements and efficiency losses, since the peak current drawn from the input supply is effectively spread out over the whole switch period. This requires that the products are synchronized. The phase offset is measured from the rising edge of the applied external clock to the center of the PWM pulse as illustrated below. SYNC clock Phase offset = 120° PWM pulse (VO/VI = 0.33) Illustration of phase offset. By default the phase offset is controlled by the defined PMBus™ address (see section PMBus™ Interface) according to the table below. This provides a way to configure phase spreading with up to eight different phase positions without using a PMBus™ command. Set PMBus address xxxx000b xxxx001b xxxx010b xxxx011b xxxx100b xxxx101b xxxx110b xxxx111b Phase offset 0° 60° 120° 180° 240° 300° 90° 270° The clock frequency of the external clock source must be stable prior to enabling the output voltage. Further, the PMBus™ command www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 19 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series The default phase offset can be overridden by using the standard PMBus™ command INTERLEAVE. The phase offset can then be defined as Phase _ offset (q) 360 q u Interleave _ order Number in _ group_ Interleave_order is in the range 0-15. Number_in_group is in the range 0-15 where a value of 0 means 16. The set resolution for the phase offset is 360° / 128 ≈ 2.8°. Giving the PMBus™ command INTERLEAVE a value of 0x0000 will revert back to the default address controlled phase offset. Murata Power Solutions provides software tools for convenient configuration of optimized phase spreading, allowing the amount of input capacitance to be significantly reduced. Initialization Procedure The product follows an internal initialization procedure after power is applied to the VIN pin (refer to figure below): 1. Self test and memory check. 2. The address pin-strap resistors are measured and the associated PMBus™ address is defined. 3. The output voltage pin-strap resistor is measured. The associated output voltage level will be loaded into operational RAM memory, unless an overriding PMBus™ command VOUT_COMMAND has been explicitly written and stored in the User Non-Volatile Memory (indicated by bit 0 in command STRAP_DISABLE). 4. Values stored in the User Non-Volatile Memory (NVM) are loaded into operational RAM memory. For PMBus™ commands listed in the table below, loaded values will be based on the output voltage level loaded in step 3 above, unless the commands have been explicitly written and stored in the User NVM. If the RSET pin-strap resistance is changed, input voltage will have to be cycled before the output voltage level is affected. If VOUT_COMMAND is changed and stored to User NVM, input voltage will have to be cycled before the output voltage related commands in the table below are re-scaled according to the new output voltage level. See section PMBus™ Interface for more information about the Non-Volatile Memories (NVM) of the product. Soft-start and Soft-stop Vout related PMBus command POWER_GOOD_ON POWER_GOOD_OFF VOUT_MAX VOUT_MARGIN_HIGH VOUT_MARGIN_LOW VOUT_OV_FAULT_LIMIT VOUT_UV_FAULT_LIMIT Loaded value unless explicitly written + stored to User NVM. 0.90 x loaded Vout level 0.85 x loaded Vout level 1.10 x loaded Vout level 1.05 x loaded Vout level 0.95 x loaded Vout level 1.15 x loaded Vout level 0.85 x loaded Vout level The soft-start and soft-stop control functionality allows the output voltage to ramp-up and ramp-down with defined timing with respect to the control of the output. This can be used to control inrush current and manage supply sequencing of multiple controllers. The rise time is the time taken for the output to ramp to its target voltage while the fall time is the time taken for the output to ramp down from its regulation voltage to less than 10% of that value. The on delay time sets a delay from when the output is enabled until the output voltage starts to ramp up. The off delay time sets a delay from when the output is disabled until the output voltage starts to ramp down. Soft-stop is disabled by default but may be enabled through the Output control 5. Check for external clock signal at the SYNC pin and wait for lock if used. On delay time Once this procedure is completed and the initialization time has passed (see Electrical Specification), the output voltage is ready to be enabled and the PMBus™ interface can be used. Rise time Off delay time Fall time VOUT Pin-strap VOUTRSET NO STRAP_DISABLE[0]=1? RAM VOUT_COMMAND YES User NVM VM VOUT_COMMAND Illustration of Soft-Start and Soft-Stop PMBus™ command ON_OFF_CONFIG. The delay and ramp times can be reconfigured using the PMBus™ commands TON_DELAY, TON_RISE, TOFF_DELAY and TOFF_FALL. READ WRITE PMBus Interface VOUT_COMMAND STRAP_DISABLE[0]=1 Loading of nominal output voltage level Note the following implications of the initialization procedure: The internal delay generator can only achieve certain discrete timing values. A written TON_DELAY/TOFF_DELAY value will be rounded to the closest achievable value, thus a TON_DELAY/OFF_ DELAY read will provide the actual set value. The internal ramp generator can only achieve certain discrete timing values for a given combination of switch frequency, output voltage level, set ramp time and trim data. These values are close, but not www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 20 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series exactly the same, when any of the relevant parameters are altered. A written TON_RISE/TOFF_FALL value will be rounded to the closest achievable value, thus a TON_RISE/TOFF_FALL read will provide the actual set value. Voltage Tracking The product supports tracking of the output from a master voltage applied to the CS_VTRK pin. To select the tracking mode, a resistance ≤ 4.22 kΩ must be connected between the VSET and PREF pins. Refer to Electrical Specification for default on delay time and rise time and the configurability ranges and resolutions. The specification provided for soft-start applies also for soft-stop, if enabled. The tracking ratio used is controlled by an internal feedback divider RDIV and an external resistive voltage divider (R1, R2) which is placed from the supply being tracked to GND pins. Output Voltage Sequencing A group of products may be configured to power up in a predetermined sequence. This feature is especially useful when powering advanced processors, FPGAs, and ASICs that require one supply to reach its operating voltage prior to another. Multi-product sequencing can be achieved by configuring the start delay and rise time of each device through the PMBus™ interface and by connecting the CTRL pin of each product to a common enable signal. VTRACK (MASTER) OKDL R2 max 1.2V CS_VTRK RDIV VOUT (SLAVE) VSET R1 VOUT RSET PREF Voltage GND RSET 4.22 k VOUT1 Tracking Mode Configuration VOUT2 In tracking mode the output voltage is regulated to the lower of: Eq. 5 Time Illustration of Output Voltage Sequencing Pre-Bias Startup Capability Pre-bias startup often occurs in complex digital systems when current from another power source is fed back through a dual-supply logic component, such as FPGAs or ASICs. The product incorporates synchronous rectifiers, but will not sink current during startup, or turn off, or whenever a fault shuts down the product in a pre-bias condition. When the output is enabled the product checks the output for the presence of pre-bias voltage. If the pre-bias voltage is above the output overvoltage threshold the product will not attempt soft-start. If the prebias voltage is less than 200 mV the soft-start is performed assuming no pre-bias. If the pre-bias voltage is above 200 mV but below target output voltage, the product ramps up the output voltage from the prebias voltage to the target regulation as shown in the figure below. Voltage Soft-start ramp time VOUT VTRACK R1 u RDIV R1 R 2 or the output voltage defined by the PMBus™ command VOUT_COMMAND. RDIV is automatically selected based on the value of VOUT_COMMAND as shown in the table below. If VOUT_COMMAND is not defined by the user, it will default to 5.25 V with RDIV= 0.20272. VOUT_COMMAND [V] < 0.99 0.99 to < 1.12 1.12 to < 1.28 1.28 to < 1.50 1.50 to < 1.82 1.82 to < 2.29 2.29 to < 3.12 3.12 to < 5.25 VOUT_COMMAND not user defined => 5.25 RDIV 0.99547 0.88222 0.76897 0.65572 0.54247 0.42922 0.31597 0.20272 0.20272 For best tracking accuracy it is recommended that once the product is powered up, the VOUT_COMMAND should not be changed so as to cause a change to the operational RDIV. If such a change in VOUT_ COMMAND is required, the user should save the new value to User Non-Volatile Memory (using STORE_USER_ALL command) and recycle the input voltage to set a new RDIV operational value. To simplify resistor selection it is recommended to fix R1 at 10 kΩ and use the following equation to determine R2: Time Illustration of Pre-Bias Startup Eq. 6 · § VTRACK R2(k:) = R1 u ¨¨ 1¸¸ ¹ © RDIV u VOUT www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 21 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series R2 must be chosen so that the CS_VTRK input does not exceed 1.2 V. As seen in Eq. 5, if the resistor-divider ratio from R1//R2 is chosen such that it is equal to the operational RDIV, the output voltage follows the tracking voltage coincidentally. For all other cases, the output voltage follows a ratiometric tracking. These two modes of tracking are further described below. 1. Coincident tracking. Output voltage is ramped at the same rate as the VTRACK voltage. To achieve coincident tracking the desired output voltage should be set by the PMBus™ command VOUT_COMMAND. R2 should be set so that R2 = R1 / RDIV – R1. The output will stop ramping when the VOUT_COMMAND level is reached. Since the voltage at the CS_VTRK pin must be below 1.2 V, coincident tracking will not be possible in all cases. A higher R2 value may be required, giving a ratiometric tracking instead. Voltage R1 / (R1 + R2) = RDIV VTRACK VOUT_ COMMAND VOUT Time Coincident Voltage Tracking Example: External VTRACK = 3.3 V Target VOUT = 2.5 V R1 = 10 kΩ VOUT_COMMAND = 2.5 V => RDIV = 0.31597 R2 = 10 / 0.31597– 10 = 21.6 kΩ ⎛ ⎞ 3.3 R 2 = 10 × ⎜ − 1⎟ = 115kΩ ⎟ ⎜ 0.20272 × 1.3 ⎝ ⎠ During voltage tracking compensation calibration is triggered when the output voltage is above 450 mV and stable within a 100 mV window for two consecutive measurements at 10 ms intervals. When calibration is complete, the power good (PG) output is asserted. The PG output remains asserted until the output voltage falls below 450 mV, as verified at 10 ms intervals. For this reason, the PG output may remain high for as much as 10 ms after the output voltage has fallen below 450 mV. When voltage tracking is enabled the output over voltage protection limit is set 12% above VOUT_COMMAND as default. This limit may be reconfigured using the PMBus™ command VOUT_OV_FAULT_LIMIT. Output under voltage protection is not functional in tracking mode. Soft-start parameters TON_DELAY and TON_RISE are not functional in tracking mode and will be set to their minimum values to prevent interference with tracking. TOFF_DELAY and TOFF_FALL can be used if soft-stop is enabled. In such case the output voltage will follow the least of the output levels given by the soft-stop parameters and the tracking equations. General The product is designed to operate in different thermal environments and sufficient cooling must be provided to ensure reliable operation. Cooling is achieved mainly by conduction, from the pins to the host board, and convection, which is dependent on the airflow across the product. Increased airflow enhances the cooling of the product. The Output Current Derating graph found in the Output section for each model provides the available output current vs. ambient air temperature and air velocity at specified VI. The product is tested on a 254 x 254 mm, 35 μm (1 oz), test board mounted vertically in a wind tunnel with a cross-section of 608 x 203 mm. The test board has 8 layers. R1 / (R1 + R2) < RDIV VT RACK VTRACK u RDIV Eq. 7 => Thermal Consideration 2. Ratiometric tracking. Output voltage is ramped at a rate that is a percentage of the VTRACK voltage. To achieve ratiometric tracking, R2 should be set according to Eq. 6 with VOUT being the desired output voltage. The PMBus™ command VOUT_COMMAND should be set equal to or higher than the output voltage given by Eq. 5, or not being set at all giving the default VOUT_COMMAND value 5.25 V. Since the target voltage level is decided by the R1//R2 divider there will be a small regulation inaccuracy due to the tolerance of the resistors. Note also that VOUT will be higher than VTRACK if R1 / (R1 + R2) > RDIV. Voltage Example: External VTRACK = 3.3 V Target VOUT = 1.3 V VOUT_COMMAND not set => RDIV = 0.20272 R1 = 10 kΩ R1 R2 V OUT Proper cooling of the product can be verified by measuring the temperature at positions P1, P2 and P3. The temperature at these positions should not exceed the max values provided in the table below. Note that the max value is the absolute maximum rating (non destruction) and that the electrical Output data is guaranteed up to TP1 +95°C. Time Ratiometric Voltage Tracking www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 22 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Definition of Product Operating Temperature The product operating temperature is used to monitor the temperature of the product. Proper thermal conditions can be verified by measuring the temperature at positions P1, P2 and P3. The temperature at these position (TP1,TP2, TP3) should not exceed the maximum temperatures in the table below. The number of measurement points may vary with different thermal design and topology. Position P1 P2 P3 Description T3, FET Reference point L1, Inductor N1, Control circuit Max Temperature 125°C * 125°C * (115°C **) 115°C * * A guard band of 5 °C is applied to the maximum recorded component temperatures when calculating output current derating curves. ** See section Alternative thermal verification. AIR FLOW P2 P1 P3 1. Continue operating without interruption (this could result in permanent damage to the product). 2. Continue operating for a given delay period, followed by an output voltage shutdown if the fault still exists. 3. Immediate and definite shutdown of output voltage until the fault is cleared by PMBus™ or the output voltage is re-enabled. 4. Immediate shutdown of output voltage while the fault is present. Operation resumes and the output is enabled when the fault condition no longer exists. Default response is 4. The OTP protection uses hysteresis so that the fault exists until the temperature has fallen to a certain level (OT_ WARN_LIMIT) below the fault threshold. The default OTP threshold and hysteresis are specified in Electrical Characteristics. The OTP limit, hysteresis and response can be reconfigured using the PMBus™ commands OT_FAULT_LIMIT, OT_WARN_LIMIT and OT_FAULT_RESPONSE. The product also incorporates a non-configurable hard-coded thermal shutdown associated with the temperature monitored at position P3 to ensure long-term flash-memory integrity. See Electrical Characteristics. Connections Temperature positions and air flow direction. Top view. Definition of Reference Temperature TP1 The reference temperature is used to monitor the temperature limits of the product. Temperature above maximum TP1, measured at the reference point P1 is not allowed and may cause degradation or permanent damage to the product. TP1 is also used to define the temperature range for normal operating conditions. TP1 is defined by the design and used to guarantee safety margins, proper operation and high reliability of the product. Alternative Thermal Verification Since it is difficult to access positions P1 and P3 of the product, measuring the temperature at only position P2 is an alternative method to verify proper thermal conditions. If measuring only TP2 the maximum temperature of P2 must be lowered since in some operating conditions TP1 will be higher than TP2. Using a temperature limit of 115°C for TP2 will make sure that the temperatures at all points P1, P2 and P3 stay below their maximum limits. Pin layout, bottom view. The table below gives a brief description of the functionality of each pin. A more detailed description can be found in the different subsections of the Operating Information section. Over Temperature Protection (OTP) The internal temperature of the product is continously monitored at position P3. When the internal temperature rises above the configured threshold level the product will respond as configured. The product can respond in a number of ways as follows: www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 23 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Pin 1A, 1B, 2A, 2B, 2C, 2D 3A, 3B, 4A, 4B, 5A, 5B 5C, 6A, 6B, 6C Designation Function 1C +S 1D VOUT Output Voltage GND Power Ground VIN -S 1E PG 1F SA0 3E SA1 2F VSET 3F PREF 6D CTRL 2E SYNC 5F SALERT 6E SDA 6F SCL 4F CS_VTRK 4E 5D, 5E RSVD NC Input Voltage Positive sense. Connect to output voltage close to the load Negative sense. Connect to power ground close to the load. Power Good output. Asserted high when the product is ready to provide regulated output voltage to the load. Open drain. See section Power Good. PMBus™ address pin strap. Used with external resistors to assign a unique PMBus™ address to the product. See section PMBus™ Interface. Output voltage pin strap. Used with external resistor to set the nominal output voltage or to select tracking mode. See section Output Voltage Adjust using Pin-strap Resistor. Pin-strap reference. Ground reference for pin-strap resistors. Remote Control. Can be used to enable/disable the output voltage of the product. See section Remote Control. External switching frequency synchronization input. See section Synchronization. PMBus™ Alert. Asserted low when any of the configured protection mechanisms indicate a fault. PMBus™ Data. Data signal for PMBus™ communication. See section PMBus™ Interface. PMBus™ Clock. Clock for PMBus™ communication. See section PMBus™ Interface. Voltage Tracking input. Allows for tracking of output voltage to an external voltage. See section Voltage Tracking. In normal operation when tracking is not used, this pin must be connected to PREF. Reserved. Connect to PREF. No connection Unused Pins Unused pins should be connected according to the table below. Note that connection of CS_VTRK to PREF is required for normal standalone operation. VSET should always have a pin strap resistor. Unused Pin CS_VTRK CTRL RSVD SYNC SA0 SA1 SDA SCL PG SALERT Connection PREF. Required for normal operation Open (pin has internal pull-up) PREF or pulled down to PREF PREF or pulled down to PREF PREF or Open PREF or Open Pull-up resistor to voltage > 2 V Pull-up resistor to voltage > 2 V Open Open Typical Application Circuit VIN VIN CI VOUT VOUT +S -S CO CTRL L O A D PG RSET SA0 SA1 VSET 2.7-3.6 V PREF RSA0 RSA1 SALERT SCL CS_VTRK SDA 3 x RPU = 2.2 k SYNC RSVD GND SALERT SCL SDA DGND Typical standalone operation with PMBus communication. PCB Layout Consideration The radiated EMI performance of the product will depend on the PCB layout and ground layer design. If a ground layer is used, it should be connected to the output of the product and the equipment ground or chassis. A ground layer will increase the stray capacitance in the PCB and improve the high frequency EMC performance. Further layout recommendations are listed below. The pin strap resistors, RSET, and RSA0/RSA1 should be placed as close to the product as possible to minimize loops that may pick up noise. Avoid current carrying planes under the pin strap resistors and the PMBus™ signals. The capacitors CI should be placed as close to the input pins as possible. The capacitors CO should be placed close to the load. The point of output voltage sense should be “downstream” of CO according to figure below. Care should be taken in the routing of the connections from the sensed output voltage to the S+ and S– terminals. These sensing connections should be routed as a differential pair, preferably between ground planes which are not carrying high currents. The routing should avoid areas of high electric or magnetic fields. If possible use planes on several layers to carry VI, VO and GND. There should be a large number of vias close to the VIN, VOUT and GND pads in order to lower input and output impedances and improve heat spreading between the product and the host board. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 24 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Input voltage (READ_VIN) VO LOAD Output voltage (READ_VOUT) GND Output current (READ_IOUT) -S +S Internal junction temperature (READ_TEMPERATURE_1) Switching frequency (READ_FREQUENCY) CO Duty cycle (READ_DUTY_CYCLE) CI VI GND RSA0, RSE SET, ET, RSA1 SCL SDA SYNC Layout guidelines PMBus™ Interface This product provides a PMBus™ digital interface that enables the user to configure many aspects of the device operation as well as to monitor the input and output voltages, output current and device temperature. The product can be used with any standard two-wire I2C or SMBus host device. In addition, the product is compatible with PMBus™ version 1.1 and includes an SALERT line to help mitigate bandwidth limitations related to continuous fault monitoring. The PMBus™ signals, SCL, SDA and SALERT require passive pull-up resistors as stated in the SMBus Specification. Pull-up resistors are required to guarantee the rise time as follows: W RPCp d 1Ps Reading Set Parameters To clearly display the true performance of the product, PMBus™ command reads of set levels, limits and timing parameters will return the internally used values. For this reason, due to rounding or internal representation in the controller of the product, there may be a difference between written and read value of a PMBus™ command. This applies to PMBus™ commands of type Linear or VoutLinear. When verifying write transactions, tolerances according to the table below can be used. PMBus™ Command COMP_MODEL VIN_ON VIN_OFF VIN_UV_FAULT_LIMIT VIN_OV_FAULT_LIMIT IOUT_OC_FAULT_LIMIT TON_DELAY TOFF_DELAY TON_RISE TOFF_FALL VOUT_COMMAND VOUT_MAX VOUT_MARGIN_HIGH VOUT_MARGIN_LOW VOUT_TRANSITION_RATE VOUT_OV_FAULT_LIMIT VOUT_UV_FAULT_LIMIT POWER_GOOD_ON POWER_GOOD_OFF Read Back Accuracy ±0 ±0.1 V ±0.1 A ±0.3 ms ±0.4 ms ±0.001 V ±0.5 V ±0.01 V Non-Volatile Memory (NVM) The product incorporates two Non-Volatile Memory areas for storage of the supported PMBus™ commands; the Default NVM and the User NVM. where Rp is the pull-up resistor value and Cp is the bus loading. The maximum allowed bus load is 400 pF. The pull-up resistor should be tied to an external supply voltage in range from 2.7-3.6 V, which should be present prior to or during power-up. If the proper power supply is not available, voltage dividers may be applied. Note that in this case, the resistance in the equation above corresponds to parallel connection of the resistors forming the voltage divider. The Default NVM is pre-loaded with Murata Power Solutions factory default values. The Default NVM is write-protected and can be used to restore the Murata Power Solutions factory default values through the command RESTORE_DEFAULT_ALL. The RESTORE_DEFAULT_ALL command will load a nominal output level of 0 V. Therefore, after a RESTORE_DEFAULT_ALL command is sent, the input voltage must be cycled in order to load correct output voltage level according to VSET pin-strap resistor (see section Startup procedure). Monitoring via PMBus™ It is possible to monitor a wide variety of parameters through the PMBus™ interface. Fault conditions can be monitored using the SALERT pin, which will be asserted when any number of pre-configured fault or warning conditions occur. It is also possible to continuously monitor one or more of the power conversion parameters including but not limited to the following: The User NVM is pre-loaded with Murata Power Solutions factory default values. The User NVM is writable and open for customization. The values in the User NVM are loaded during initialization whereafter commands can be changed through the PMBus™ Interface. The STORE_USER_ALL command will store the changed parameters to the User NVM. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 25 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series STORE_USER_ALL User NVM Murata factory default Customizable RESTORE_USER_ALL INITIALIZATION Default NVM Murata factory default Write-protected RESTORE_DEFAULT_ALL RAM WRITE PMBus interface READ Protecting Commands The user may write-protect specific PMBus™ commands in the User NVM by following the steps below. 1. Enter the default password 0x0000 through the command USER_ PASSWD. After the correct password is entered, SECURITY_LEVEL will read back 0x01 instead of default 0x00. 2. If desired, define a new password by writing it to the USER_LOCK command. 3. Define which commands should be locked by using the 256 bit command USER_CONF. Setting bit X will write-protect the PMBus™ command with code X. 4. Send command STORE_USER_ALL. RSA0 [kΩ] ≤ 4.22 5.11 6.19 7.15 8.25 9.53 11.0 12.7 14.7 17.8 21.5 26.1 31.6 38.3 44.2 51.1 59.0 68.1 86.6 115 140 169 205 ≥ 237 RSA1 [kΩ] ≤ 4.22 9.53 21.5 51.1 140 0x0A 0x0B 0x0C 0x0D 0x0E 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 0x17 0x18 0x19 0x1A 0x1B 0x1C 0x1D 0x1E 0x1F 0x20 0x21 5.11 11.0 26.1 59.0 169 0x22 0x23 0x24 0x25 0x26 0x27 0x28 0x29 0x2A 0x2B 0x2C 0x2D 0x2E 0x2F 0x30 0x31 0x32 0x33 0x34 0x35 0x36 0x37 0x38 0x39 6.19 12.7 31.6 68.1 205 0x3A 0x3B 0x3C 0x3D 0x3E 0x3F 0x40 0x41 0x42 0x43 0x44 0x45 0x46 0x47 0x48 0x49 0x4A 0x4B 0x4C 0x4D 0x4E 0x4F 0x50 0x51 7.15 14.7 38.3 86.6 237 0x52 0x53 0x54 0x55 0x56 0x57 0x58 0x59 0x5A 0x5B 0x5C 0x5D 0x5E 0x5F 0x60 0x61 0x62 0x63 0x64 0x65 0x66 0x67 0x68 0x69 8.25 17.8 44.2 115 ≥ 274 0x6A 0x6B 0x6C 0x6D 0x6E 0x6F 0x70 0x71 0x72 0x73 0x74 0x75 0x76 0x77 0x78 0x79 0x7A 0x7B 0x7C 0x7D 0x7E 0x7F 0x7F 0x7F 5. Cycle the input voltage. Software Tools for Design and Production Murata Power Solutions provides software tools for configuration and monitoring of this product via the PMBus™ interface. For more information please contact your local Murata Power Solutions sales representative. PMBus™ Addressing The PMBus™ address should be configured with resistors connected between the SA0/SA1 pins and the PREF pin, as shown in the table and figure below. Note that five different values of RSA1 produce the same address. Recommended resistor values for hard-wiring PMBus™ addresses are shown in the table. 1% tolerance resistors are required. The configurable PMBus™ addresses range from 0x0A to 0x7F. In total 118 device address combinations are provided. SA0 SA1 RSA1 RSA0 PREF Schematic of connection of address resistor. Optional PMBus™ Addressing The user may leave SA0/SA1 open or shorted to PREF. Shorting SA0/SA1 to PREF corresponds to RSA0/RSA1 ≤ 4.22 kΩ in the address table above. Leaving SA0/SA1 open corresponds to RSA0/RSA1 ≥ 274 kΩ in the address table above. Reserved Addresses Addresses listed in the table below are reserved or assigned according to the SMBus specification and may not be usable. Refer to the SMBus specification for further information. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 26 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Address 0x00 0x01 0x02 0x03 - 0x07 0x08 0x09 - 0x0B 0x0C 0x28 0x2C - 0x2D 0x37 0x40 - 0x44 0x48 - 0x4B 0x61 0x78 - 0x7B 0x7C - 0x7F Comment General Call Address / START byte CBUS address Address reserved for different bus format Reserved for future use SMBus Host Assigned for Smart Battery SMBus Alert Response Address Reserved for ACCESS.bus host Reserved by previous versions of the SMBus specification Reserved for ACCESS.bus default address Reserved by previous versions of the SMBus specification Unrestricted addresses SMBus Device Default Address 10-bit slave addressing Reserved for future use I2C/SMBus – Timing PMBus™ Command STORE_USER_ALL STORE_DEFAULT_ALL DEADTIME_GCTRL USER_CONF MANUF_CONF RESTORE_USER_ALL RESTORE_DEFAULT_ALL FREQUENCY_SWITCH VOUT_DROOP IOUT_CAL_GAIN ADAPTIVE_MODE FEEDBACK_EFFORT LOOP_CONFIG COMP_MODEL ZETAP Delay after Write before Additional Command 500 ms 350 ms 10 ms 0.5 ms PMBus™ Commands The product is PMBus™ compliant. The following table lists all the implemented PMBus™ read commands. For more detailed information see PMBus™ Power System Management Protocol Specification; Part I – General Requirements, Transport and Electrical Interface and PMBus™ Power System Management Protocol; Part II – Command Language. Setup and hold times timing diagram The setup time, tset, is the time data, SDA, must be stable before the rising edge of the clock signal, SCL. The hold time thold, is the time data, SDA, must be stable after the falling edge of the clock signal, SCL. If these times are violated incorrect data may be captured or meta-stability may occur and the bus communication may fail. All standard SMBus protocols must be followed, including clock stretching. Refer to the SMBus specification, for SMBus electrical and timing requirements. The bus-free time (time between STOP and START packet) according to Electrical Specification must be followed. The product supports PEC (Packet Error Checking) according to the SMBus specification. In operation cases according to the list below the product’s controller will be executing processor-intensive tasks and may not respond to PMBus™ commands. During the presence of an overcurrent fault. Just after the output voltage has been enabled. It is recommended to wait until PG is asserted (or the equivalent time) before sending commands. When sending subsequent commands to the same unit it is recommended to insert additional delays after write transactions according to the table below. Designation Standard PMBus™ Commands Control Commands PAGE OPERATION ON_OFF_CONFIG WRITE_PROTECT Output Commands CAPABILITY (read only) VOUT_MODE (read Only) VOUT_COMMAND VOUT_TRIM VOUT_CAL_OFFSET VOUT_MAX VOUT_MARGIN_HIGH VOUT_MARGIN_LOW VOUT_TRANSITION_RATE VOUT_DROOP MAX_DUTY FREQUENCY_SWITCH VIN_ON VIN_OFF IOUT_CAL_GAIN IOUT_CAL_OFFSET VOUT_SCALE_LOOP VOUT_SCALE_MONITOR COEFFICIENTS Fault Limit Commands POWER_GOOD_ON POWER_GOOD_OFF VOUT_OV_FAULT_LIMIT VOUT_OV_WARN_LIMIT Code Impl* 00h 01h 02h 10h No Yes Yes Yes 19h 20h 21h 22h 23h 24h 25h 26h 27h 28h 32h 33h 35h 36h 38h 39h 29h 2Ah 30h Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes No Yes Yes Yes Yes Yes No No No 5Eh 5Fh 40h 42h Yes Yes Yes No www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 27 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Designation VOUT_UV_WARN_LIMIT VOUT_UV_FAULT_LIMIT IOUT_OC_FAULT_LIMIT IOUT_OC_LV_FAULT_LIMIT IOUT_OC_WARN_LIMIT IOUT_UC_FAULT_LIMIT OT_FAULT_LIMIT OT_WARN_LIMIT UT_WARN_LIMIT UT_FAULT_LIMIT VIN_OV_FAULT_LIMIT VIN_OV_WARN_LIMIT VIN_UV_WARN_LIMIT VIN_UV_FAULT_LIMIT Fault Response Commands VOUT_OV_FAULT_RESPONSE VOUT_UV_FAULT_RESPONSE OT_FAULT_RESPONSE UT_FAULT_RESPONSE VIN_OV_FAULT_RESPONSE VIN_UV_FAULT_RESPONSE IOUT_OC_FAULT_RESPONSE IOUT_OC_LV_FAULT_RESPONSE IOUT_UC_FAULT_RESPONSE TON_MAX_FAULT_RESPONSE Time setting Commands TON_DELAY TON_RISE TOFF_DELAY TOFF_FALL TON_MAX_FAULT_LIMIT Status Commands (Read Only) CLEAR_FAULTS STATUS_BYTE STATUS_WORD STATUS_VOUT STATUS_IOUT STATUS_INPUT STATUS_TEMPERATURE STATUS_CML STATUS_MFR_SPECIFIC Monitor Commands (Read Only) READ_VIN READ_IIN READ_VOUT READ_IOUT READ_TEMPERATURE_1 READ_TEMPERATURE_2 READ_FAN_SPEED_1 READ_DUTY_CYCLE READ_FREQUENCY READ_POUT READ_PIN Group Commands INTERLEAVE Code 43h 44h 46h 48h 4Ah 4Bh 4Fh 51h 52h 53h 55h 57h 58h 59h Impl* No Yes Yes No No No Yes Yes No No Yes No No Yes 41h 45h 50h 54h 56h 5Ah 47h 49h 4Ch 63h Yes Yes Yes No Yes Yes Yes No No Yes 60h 61h 64h 65h 62h Yes Yes Yes Yes Yes 03h 78h 79h 7Ah 7Bh 7Ch 7Dh 7Eh 80h Yes Yes Yes Yes Yes Yes Yes Yes Yes 88h 89h 8Bh 8Ch 8Dh 8Eh 90h 94h 95h 96h 97h Yes No Yes Yes Yes Yes No Yes Yes No No 37h Yes Designation PHASE_CONTROL Identification Commands PMBUS_REVISION MFR_ID MFR_MODEL MFR_REVISION MFR_LOCATION MFR_DATE MFR_SERIAL IC_DEVICE_ID IC_DEVICE_REV Supervisory Commands STORE_DEFAULT_ALL RESTORE_DEFAULT_ALL STORE_USER_ALL RESTORE_USER_ALL Product Specific Commands ADAPTIVE_MODE FEEDBACK_EFFORT LOOP_CONFIG TEST_MODE COMP_MODEL STRAP_DISABLE MANUF_CONF MANUF_LOCK MANUF_PASSWD USER_CONF USER_LOCK USER_PASSWD SECURITY_LEVEL DEADTIME_GCTRL ZETAP Code F0h Impl* No 98h 99h 9Ah 9Bh 9Ch 9Dh 9Eh ADh AEh Yes Yes Yes Yes Yes Yes Yes Yes Yes 11h 12h 15h 16h Yes Yes Yes Yes D0h D3h D5h D9h DBh DCh E0h E1h E2h E3h E4h E5h E6h E7h E8h Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes *Impl stands for Implemented. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 28 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series MECHANICAL SPECIFICATIONS www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 29 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Soldering Information - Surface Mounting The surface mount product is intended for forced convection or vapor phase reflow soldering in SnPb or Pb-free processes. The reflow profile should be optimised to avoid excessive heating of the product. It is recommended to have a sufficiently extended preheat time to ensure an even temperature across the host PCB and it is also recommended to minimize the time in reflow. A no-clean flux is recommended to avoid entrapment of cleaning fluids in cavities inside the product or between the product and the host board, since cleaning residues may affect long time reliability and isolation voltage. General reflow process specifications Average ramp-up (TPRODUCT) Typical solder melting (liquidus) TL temperature Minimum reflow time above TL Minimum pin temperature TPIN Peak product temperature TPRODUCT Average ramp-down (TPRODUCT) Maximum time 25°C to peak SnPb eutectic Pb-free 3°C/s max 3°C/s max 183°C 221°C 30 s 210°C 225°C 6°C/s max 6 minutes 30 s 235°C 260°C 6°C/s max 8 minutes Temperature TPRODUCT maximum TPIN minimum Pin profile TL Product profile Time in reflow Maximum Product Temperature Requirements Top of the product PCB near pin A2 or A5 is chosen as reference locations for the maximum (peak) allowed product temperature (TPRODUCT) since these will likely be the warmest part of the product during the reflow process. SnPb solder processes For SnPb solder processes, the product is qualified for MSL 1 according to IPC/JEDEC standard J STD 020C. During reflow TPRODUCT must not exceed 225 °C at any time. Pb-free solder processes For Pb-free solder processes, the product is qualified for MSL 3 according to IPC/JEDEC standard J-STD-020C. During reflow TPRODUCT must not exceed 260 °C at any time. Dry Pack Information Surface mounted versions of the products are delivered in standard moisture barrier bags according to IPC/JEDEC standard J STD 033 (Handling, packing, shipping and use of moisture/reflow sensitivity surface mount devices). Using products in high temperature Pb-free soldering processes requires dry pack storage and handling. In case the products have been stored in an uncontrolled environment and no longer can be considered dry, the modules must be baked according to J STD 033. Thermocoupler Attachment Time in preheat / soak zone Time 25°C to peak all solder joints is recommended to ensure a reliable solder joint. Time Top of PWB near pin A2 or A5 for measurement of maximum product temperature, TPRODUCT Minimum Pin Temperature Recommendations Pin number C1 or D1 are chosen as reference location for the minimum pin temperature recommendation since these will likely be the coolest solder joint during the reflow process. SnPb solder processes For SnPb solder processes, a pin temperature (TPIN) in excess of the solder melting temperature, (TL, 183°C for Sn63Pb37) for more than 30 seconds and a peak temperature of 210°C is recommended to ensure a reliable solder joint. For dry packed products only: depending on the type of solder paste and flux system used on the host board, up to a recommended maximum temperature of 245°C could be used, if the products are kept in a controlled environment (dry pack handling and storage) prior to assembly. Lead-free (Pb-free) solder processes For Pb-free solder processes, a pin temperature (TPIN) in excess of the solder melting temperature (TL, 217 to 221°C for SnAgCu solder alloys) for more than 30 seconds and a peak temperature of 235°C on Pin C1 or D1 for measurement of minimum Pin (solder joint) temperature TPIN Surface Mount Assembly and Repair The LGA of the product require particular care during assembly since the LGA´s are hidden between the host board and the product’s PCB. Special procedures are required for successful rework of these products. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 30 of 31 OKDL-T/12-W12-xxx-C 12A Digital PoL DC-DC Converter Series Assembly Automatic pick and place equipment should be used to mount the product on the host board. The use of a vision system, utilizing the fiducials on the bottom side of the product, will ensure adequate accuracy. Manual mounting of solder bump products is not recommended. ROUND SPROCKET This module is not recommended for assembly on the bottom side of a customer board. If such an assembly is attempted, components may fall off the module during the second reflow process. Repair For a successful repair (removal and replacement) of a LGA product, a dedicated rework system should be used. The rework system should preferably utilize a reflow station and a bottom side heater might also be needed for the operation. The product is an open frame design with a pick up surface on a large central component (in this case the choke). This pick up surface can be used for removal of the module provided that it is glued against module PCB before removal to prevent it from separating from the module PCB. Delivery Package Information The products are delivered in antistatic carrier tape (EIA 481 standard). Carrier Tape Specifications Material Surface resistance Bakeability Tape width, W Pocket pitch, P1 Pocket depth, K0 Reel diameter Reel capacity Reel weight PS, antistatic < 107 Ohm/square The tape is not bakable 24 mm [0.94 inch] 20 mm [0.79 inch] 8.6 mm [0.339 inch] 330 mm [13 inch] 280 products /reel 1160 g/full reel Murata Power Solutions, Inc. 11 Cabot Boulevard, Mansfield, MA 02048-1151 U.S.A. ISO 9001 and 14001 REGISTERED This product is subject to the following operating requirements and the Life and Safety Critical Application Sales Policy: Refer to: http://www.murata-ps.com/requirements/ Murata Power Solutions, Inc. makes no representation that the use of its products in the circuits described herein, or the use of other technical information contained herein, will not infringe upon existing or future patent rights. The descriptions contained herein do not imply the granting of licenses to make, use, or sell equipment constructed in accordance therewith. Specifications are subject to change without notice. © 2016 Murata Power Solutions, Inc. www.murata-ps.com/support MDC_OKDL-T/12-W12-xxx-C.A02 Page 31 of 31