19-3796; Rev 0; 4/06 KIT ATION EVALU E L B A AVAIL High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ Fixed-Frequency, Current-Mode Control 40/60 Optimal Interleaving Internal BST Switches Internal 5V, 100mA Linear Regulator Auxiliary Linear-Regulator Driver (12V or Adjustable Down to 1V) Dual Mode™ Feedback—3.3V/5V Fixed or Adjustable Output Voltages 200kHz/300kHz/500kHz Switching Frequency Undervoltage and Thermal-Fault Protection Overvoltage-Fault Protection (MAX8744 Only) 6V to 26V Input Range 2V ±0.75% Reference Output Independent Enable Inputs and Power-Good Outputs Soft-Start and Soft-Shutdown (Voltage Ramp) 8µA (typ) Shutdown Current Ordering Information TEMP RANGE PINPACKAGE MAX8744ETJ+ -40°C to +85°C 32 Thin QFN T3255-4 (5mm x 5mm) MAX8745ETJ+ -40°C to +85°C 32 Thin QFN T3255-4 (5mm x 5mm) PART PKG CODE +Denotes lead-free package. IN LDO5 PGND DL5 LX5 24 DL3 TOP VIEW PGOODA Pin Configuration LX3 The MAX8744/MAX8745 are dual step-down, switchmode, power-supply (SMPS) controllers with synchronous rectification, intended for main 5V/3.3V power generation in battery-powered systems. Fixed-frequency operation with optimal interleaving minimizes input ripple current from the lowest input voltages up to the 26V maximum input. Optimal 40/60 interleaving allows the input voltage to go down to 8.3V before duty-cycle overlap occurs, compared to 180° out-of-phase regulators where the duty-cycle overlap occurs when the input drops below 10V. Output current sensing provides peak current-limit protection, using either an accurate sense resistor or using lossless inductor DCR current sensing. A low-noise mode maintains high light-load efficiency while keeping the switching frequency out of the audible range. An internal, fixed 5V, 100mA linear regulator powers up the MAX8744/MAX8745 and their gate drivers, as well as external keep-alive loads. When the main PWM regulator is in regulation, an automatic bootstrap switch bypasses the internal linear regulator, providing current up to 200mA. An additional adjustable linear-regulator driver with an external pnp transistor may be used with a secondary winding to provide a 12V supply, or powered directly from the main outputs to generate lowvoltage outputs as low as 1V. Independent enable controls and power-good signals allow flexible power sequencing. Voltage soft-start gradually ramps up the output voltage and reduces inrush current, while soft-shutdown gradually ramps the output voltage down, preventing negative voltage dips. The MAX8744/MAX8745 feature output undervoltage and thermal-fault protection. The MAX8744 also includes output overvoltage-fault protection. Features 23 22 21 20 19 18 17 The MAX8744/MAX8745 are available in a 32-pin, 5mm x 5mm, thin QFN package. The exposed backside pad improves thermal characteristics for demanding linear keep-alive applications. DH3 25 16 DH5 BST3 26 15 BST5 Applications PGOOD3 27 14 PGOOD5 CSL3 28 13 CSL5 12 CSH5 Dual Mode is a trademark of Maxim Integrated Products, Inc. 11 FB5 FBA 31 10 SKIP 9 FSEL + 1 2 3 4 5 6 7 8 ON3 ON5 REF GND OUTA 32 SHDN PDAs and Mobile Communicators FB3 30 ILIM Notebook and Subnotebook Computers CSH3 29 ONA 2 to 4 Li+ Cell Battery-Powered Devices MAX8744 MAX8745 DRVA Main Power Supplies THIN QFN 5mm x 5mm ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. 1 MAX8744/MAX8745 General Description MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers ABSOLUTE MAXIMUM RATINGS IN, SHDN, DRVA, OUTA to GND............................-0.3V to +28V LDO5, ON3, ON5, ONA to GND ..............................-0.3V to +6V PGOODA, PGOOD3, PGOOD5 to GND...................-0.3V to +6V CSL3, CSH3, CSL5, CSH5 to GND ..........................-0.3V to +6V REF, FB3, FB5, FBA to GND...................-0.3V to (VLDO5 + 0.3V) SKIP, FSEL, ILIM to GND........................-0.3V to (VLDO5 + 0.3V) DL3, DL5 to PGND..................................-0.3V to (VLDO5 + 0.3V) BST3, BST5 to PGND .............................................-0.3V to +34V BST3 to LX3..............................................................-0.3V to +6V DH3 to LX3 ..............................................-0.3V to (VBST3 + 0.3V) BST5 to LX5..............................................................-0.3V to +6V DH5 to LX5 ..............................................-0.3V to (VBST5 + 0.3V) GND to PGND .......................................................-0.3V to +0.3V BST3, BST5 LDO5 .................................................-0.3V to +0.3V LDO Short Circuit to GND ..........................................Momentary REF Short Circuit to GND ...........................................Momentary DRVA Current (Sinking) ......................................................30mA OUTA Shunt Current ...........................................................30mA Continuous Power Dissipation (TA = +70°C) Multilayer PC Board 32-Pin, 5mm x 5mm TQFN (derated 34.5mW/°C above +70°C) .........................2459mW Operating Temperature Range ...........................-40°C to +85°C Junction Temperature ......................................................+150°C Storage Temperature Range .............................-65°C to +150°C Lead Temperature (soldering, 10s) ................................+300°C Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS INPUT SUPPLIES (Note 1) VIN Input Voltage Range VIN VIN Operating Supply Current IIN LDO5 in regulation 5.4 26.0 IN = LDO5, VCSL5 < 4.4V 4.5 5.5 V LDO5 switched over to CSL5, either SMPS on 20 36 µA VIN Standby Supply Current IIN(STBY) VIN = 6V to 26V, both SMPS off, includes ISHDN 65 120 µA VIN Shutdown Supply Current IIN(SHDN) VIN = 6V to 26V 8 20 µA 3.5 4.5 mW Quiescent Power Consumption PQ Both SMPS on, FB3 = FB5 = LDO5, SKIP = GND, VCSL3 = 3.5V, VCSL5 = 5.3V, VOUTA = 15V, PIN + PCSL3 + PCSL5 + POUTA MAIN SMPS CONTROLLERS 3.3V Output Voltage in Fixed Mode VOUT3 VIN = 6V to 26V, SKIP = FB3 = LDO5, 0 < VCSH3 - VCSL3 < 50mV (Note 2) 3.265 3.315 3.365 V 5V Output Voltage in Fixed Mode VOUT5 VIN = 6V to 26V, SKIP = FB5 = LDO5, 0 < VCSH5 - VCSL5 < 50mV (Note 2) 4.94 5.015 5.09 V VIN = 6V to 26V, FB3 or FB5 duty factor = 20% to 80% 1.980 2.010 2.040 VIN = 6V to 26V, FB3 or FB5 duty factor = 50% 1.990 2.010 2.030 Feedback Voltage in Adjustable Mode (Note 2) 2 VFB_ V _______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL Output Voltage Adjust Range CONDITIONS Either SMPS 3.0 Feedback Input Leakage Current VFB3 = VFB5 = 2.1V DC Load Regulation Either SMPS, SKIP = LDO5, 0 < VCSH_ - VCSL_ < 50mV Line Regulation Error Either SMPS, 6V < VIN < 26V Maximum Duty Factor DMAX Minimum On-Time tONMIN SMPS3-to-SMPS5 Phase Shift MAX UNITS 5.5 V VLOO5 - 1.0 VLOO5 - 0.4 V +0.1 µA -0.1 FSEL = GND fOSC TYP 2.0 FB3, FB5 Dual Mode Threshold Operating Frequency (Note 1) MIN -0.1 % 0.03 170 200 %/V 230 FSEL = REF 270 300 330 FSEL = LDO5 425 500 575 (Note 1) 97.5 SMPS5 starts after SMPS3 kHz 99 % 100 ns 40 % 144 Deg CURRENT LIMIT ILIM Adjustment Range Current-Sense Input Leakage Current Current-Limit Threshold (Fixed) CSH3 = CSH5 = GND or LDO5 VLIMIT Current-Limit Threshold (Adjustable) VLIMIT Current-Limit Threshold (Negative) VNEG Current-Limit Threshold (Zero Crossing) VZX VCSH_ - VCSL _, ILIM = LDO5 VCSH_ - VCSL _ ILIM Leakage Current V -1 +1 µA mV 45 50 55 185 200 215 VILIM = 1.00V 94 100 106 -67 -60 -53 VCSH_ - VCSL _, SKIP = ILIM = LDO5 VCSH_ - VCSL _, SKIP = LDO5, adjustable mode, percent of current limit VCSH_ - VCSL _, SKIP = GND, ILIM = LDO5 VIDLE VCSH_ - VCSL _, SKIP = GND VIDLE VCSH_ - VCSL _, SKIP = REF ILIM = GND or REF -120 mV mV % 0 3 6 mV 6 10 14 mV With respect to current-limit threshold (VLIMIT) ILIM = LDO5 Idle Mode Threshold (Low Audible-Noise Mode) VREF VILIM = 2.00V ILIM = LDO5 Idle Mode™ Threshold 0.5 20 2.5 With respect to current-limit threshold (VLIMIT) 5 % 7.5 10 -1 mV % +1 µA Idle Mode is a trademark of Maxim Integrated Products, Inc. _______________________________________________________________________________________ 3 MAX8744/MAX8745 ELECTRICAL CHARACTERISTICS (continued) MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS Soft-Start Ramp Time tSSTART Measured from the rising edge of ON_ to full scale 2 ms Soft-Stop Ramp Time tSSTOP Measured from the falling edge of ON_ to full scale 4 ms INTERNAL FIXED LINEAR REGULATORS LDO5 Output Voltage VLDO5 ON5 = GND, 6V < VIN < 26V, 0 < ILDO5 < 100mA LDO5 Undervoltage-Lockout Fault Threshold Rising edge, hysteresis = 1% (typ) LDO5 Bootstrap Switch Threshold Rising edge of CSL5, hysteresis = 1% (typ) LDO5 Bootstrap Switch Resistance LDO5 to CSL5, VCSL5 = 5V, ILDO5 = 50mA Short-Circuit Current LDO5 = GND, ON5 = GND Short-Circuit Current (Switched over to CSL_) LDO5 = GND, VCSL5 > 4.7V 4.85 4.35 200 4.95 5.10 V 225 450 mA 4.55 4.70 V 1 5 Ω 225 450 mA 425 mA AUXILIARY LINEAR REGULATOR DRVA Voltage Range VDRVA DRVA Drive Current FBA Regulation Threshold 0.5 VFBA = 0.965V, VDRVA = 5V VFBA FBA Load Regulation VDRVA = 5V, IDRVA = 1mA (sink) 0.4 10 0.98 VDRA = 5V, IDRVA = 0.5mA to 5mA OUTA Shunt Trip Level Rising edge FBA Leakage Current VFBA = 1.035V Secondary Feedback Regulation Threshold VDRVA - VOUTA 25 IOUTA VDRVA = VOUTA = 25V VREF LDO5 in regulation, IREF = 0 V mA 1.00 1.02 V -1.2 -2.2 % 26 -0.1 DL5 Pulse Width OUTA Leakage Current 26.0 VFBA = 1.05V, VDRVA = 5V 27 V +0.1 µA 0 V 1/ 3fOSC µs 50 µA 2.015 V +10 mV REFERENCE (REF) Reference Voltage Reference Load-Regulation Error REF Lockout Voltage ΔVREF VREF(UVLO) IREF = -5µA to +50µA 1.985 2.00 -10 Rising edge, hysteresis = 100mV (typ) 1.90 V FAULT DETECTION Output Overvoltage Trip Threshold (MAX8744 Only) Output Overvoltage Fault Propagation Delay (MAX8744 Only) 4 With respect to error-comparator threshold tOVP 50mV overdrive 8 11 10 _______________________________________________________________________________________ 14 % µs High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL Output Undervoltage Protection Trip Threshold Output Undevoltage Fault Propagation Delay Output Undervoltage Protection Blanking Time With respect to error-comparator threshold tUVP tBLANK tPGOOD_ PGOOD_ Output Low Voltage PGOOD_ Leakage Current Thermal-Shutdown Threshold MIN TYP MAX UNITS 65 70 75 % 50mV overdrive 10 From rising edge of ON_ with respect to fSW With respect to error-comparator threshold, hysteresis = 1% (typ) PGOOD_ Lower Trip Threshold PGOOD_ Propagation Delay CONDITIONS 5000 6144 7000 1/fOSC -12 -10 -8 % Falling edge, 50mV overdrive 10 Rising edge, 50mV overdrive 1 ISINK = 1mA IPGOOD_ tSHDN µs High state, PGOOD_ forced to 5.5V Hysteresis = 15°C µs 0.4 V 1 µA +160 °C GATE DRIVERS DH_ Gate-Driver On-Resistance RDH DL_ Gate-Driver On-Resistance RDL DH_ Gate-Driver Source/Sink Current DL_ Gate-Driver Source Current DL_ Gate-Driver Sink Current 1.3 1.7 5 DL_, low state 0.6 3 DH_ forced to 2.5V, BST_ – LX_ forced to 5V IDL (SOURCE) DL_ forced to 2.5V IDL (SINK) DL_ forced to 2.5V tDEAD Internal BST_ Switch OnResistance RBST 5 DL_, high state IDH Dead Time BST_ Leakage Current BST_ – LX_ forced to 5V Ω Ω 2 A 1.7 A 3.3 A DH_low to DL_high 15 45 DL_low to DH_high 15 44 IBST = 10mA 5 VBST_ = 26V 2 ns Ω 20 µA INPUTS AND OUTPUTS SHDN Input Trip Level ONA Logic Input Voltage Rising trip level 1.1 1.6 2.2 Falling trip level 0.96 1 1.04 Hysteresis = 600mV (typ) High 2.4 Low 0.8 SMPS off level/clear fault level ON3, ON5 Input Voltage V V 0.8 Delay start level 1.9 SMPS on level 2.4 2.1 V _______________________________________________________________________________________ 5 MAX8744/MAX8745 ELECTRICAL CHARACTERISTICS (continued) MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER SYMBOL CONDITIONS SKIP, FSEL Tri-Level Input Logic MIN High VLDO5 - 0.4 REF 1.65 TYP GND Input Leakage Current MAX 2.35 UNITS V 0.5 SKIP, FSEL forced to GND or LDO5 -1 +1 SHDN forced to GND or 26V -1 +1 µA ELECTRICAL CHARACTERISTICS (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = -40°C to +85°C, unless otherwise noted.) (Note 3) PARAMETER SYMBOL CONDITIONS MIN MAX LDO5 in regulation 5.4 26.0 IN = LDO5, VCSL5 < 4.4V 4.5 5.5 UNITS INPUT SUPPLIES (Note 1) VIN Input Voltage Range VIN VIN Operating Supply Current IIN LDO5 switched over to CSL5, either SMPS on 40 µA VIN = 6V to 26V, both SMPS off, includes ISHDN 120 µA 20 µA 4.5 mW VIN Standby Supply Current IIN(STBY) VIN Shutdown Supply Current IIN(SHDN) VIN = 6V to 26V Quiescent Power Consumption PQ V Both SMPS on, FB3 = FB5 = LDO5; SKP = GND, VCSL3 = 3.5V, VCSL5 = 5.3V, VOUTA = 15V, PIN + PCSL3 + PCSL5 MAIN SMPS CONTROLLERS 3.3V Output Voltage in Fixed Mode VOUT3 VIN = 6V to 26V, SKIP = FB3 = LDO5, 0 < VCSH3 - VCSL3 < 50mV (Note 2) 3.255 3.375 V 5V Output Voltage in Fixed Mode VOU5 VIN = 6V to 26V, SKIP = FB5 = LDO5, 0 < VCSH5 - VCSL5 < 50mV (Note 2) 4.925 5.105 V Feedback Voltage in Adjustable Mode VFB_ VIN = 6V to 26V, FB3 or FB5 duty factor = 20% to 80% (Note 2) 1.974 2.046 V 2.0 5.5 V 3V VLDO5 - 0.4 V 170 230 Output Voltage Adjust Range Either SMPS FB3, FB5 Dual Mode Threshold FSEL = GND Operating Frequency (Note 1) Maximum Duty Factor 6 fOSC DMAX FSEL = REF 270 330 FSEL = LDO5 425 575 97 _______________________________________________________________________________________ kHz % High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = -40°C to +85°C, unless otherwise noted.) (Note 3) PARAMETER SYMBOL CONDITIONS MIN MAX UNITS 0.5 VREF V 44 56 mV CURRENT LIMIT ILIM Adjustment Range Current-Limit Threshold (Fixed) VLIMIT VCSH_ - VCSL _, ILIM = LDO5 Current-Limit Threshold (Adjustable) VLIMIT VCSH_ - VCSL _ VILIM = 2.00V 185 215 VILIM = 1.00V 93 107 ON5 = GND, 6V < VIN < 26V, 0 < ILDO5 < 100mA 4.85 5.10 V Rising edge, hysteresis = 1% (typ) 3.7 4.1 V LDO5 Bootstrap Switch Threshold Rising edge of CSL5, hysteresis = 1% (typ) 4.30 4.75 V Short-Circuit Current LDO5 = GND, ON5 = GND 450 mA Short-Circuit Current (Switched over to CSL_) LDO5 = GND, VCSL5 > 4.7V mV INTERNAL FIXED LINEAR REGULATORS LDO5 Output Voltage VLDO5 LDO5 Undervoltage-Lockout Fault Threshold 200 mA AUXILIARY LINEAR REGULATOR DRVA Voltage Range VDRVA 0.5 VFBA = 1.05V, VDRVA = 5V DRVA Drive Current VFBA = 0.965V, VDRVA = 5V FBA Regulation Threshold VFBA VDRVA = 5V, IDRVA = 1mA (sink) OUTA Shunt Trip Level 26 0.4 10 V mA 0.98 1.02 V 25 27 V 1.980 2.020 V REFERENCE (REF) Reference Voltage VREF LDO5 in regulation, IREF = 0 _______________________________________________________________________________________ 7 MAX8744/MAX8745 ELECTRICAL CHARACTERISTICS (continued) MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1, VIN = 12V, both SMPS enabled, FSEL = REF, SKIP = GND, ILIM = LDO5, FBA = LDO5, IREF = ILDO5 = IOUTA = no load, TA = -40°C to +85°C, unless otherwise noted.) (Note 3) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS FAULT DETECTION Output Overvoltage Trip Threshold (MAX8744 Only) With respect to error comparator threshold 8 14 % Output Undervoltage Protection With respect to error comparator threshold 65 75 % PGOOD_ Lower Trip Threshold With respect to error comparator threshold, hysteresis = 1% -12 -8 % PGOOD_ Output Low Voltage ISINK = 1mA 0.4 V BST_ – LX_ forced to 5V 5 Ω DL_, high state 5 DL_, low state 3 GATE DRIVERS DH_ Gate-Driver On-Resistance DL_ Gate-Driver On-Resistance RDH RDL Ω INPUTS AND OUTPUTS SHDN Input Trip Level ONA Logic Input Voltage Rising trip level 1.0 2.3 Falling trip level 0.96 1.04 Hysteresis = 600mV High 2.4 Low 0.8 SMPS off level/clear fault level ON3, ON5 Input Voltage Tri-Level Input Logic V 0.8 Delay start level 1.9 SMPS on level 2.4 SKIP, FSEL V High VLDO5 - 0.4 REF 1.65 GND 2.1 V 2.35 V 0.5 Note 1: The MAX8744/MAX8745 cannot operate over all combinations of frequency, input voltage (VIN), and output voltage. For large input-to-output differentials and high switching-frequency settings, the required on-time may be too short to maintain the regulation specifications. Under these conditions, a lower operating frequency must be selected. The minimum on-time must be greater than 150ns, regardless of the selected switching frequency. On-time and off-time specifications are measured from 50% point to 50% point at the DH_ pin with LX_ = GND, VBST_ = 5V, and a 250pF capacitor connected from DH_ to LX_. Actual in-circuit times may differ due to MOSFET switching speeds. Note 2: When the inductor is in continuous conduction, the output voltage has a DC-regulation level lower than the error-comparator threshold by 50% of the ripple. In discontinuous conduction (SKIP = GND, light load), the output voltage has a DC regulation level higher than the trip level by approximately 1% due to slope compensation. Note 3: Specifications from -40°C to +85°C are guaranteed by design, not production tested. 8 _______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers 5V OUTPUT EFFICIENCY vs. LOAD CURRENT 90 70 20V 60 80 70 LOW-NOISE MODE 60 SKIP MODE PWM MODE 0.1 1 LOAD CURRENT (A) 50 10 3.3V OUTPUT EFFICIENCY vs. LOAD CURRENT 70 1.0 70 LOW-NOISE MODE 0.1 1 LOAD CURRENT (A) SKIP MODE 3.36 PWM MODE 0.01 0.1 1 LOAD CURRENT (A) PWM MODE SUPPLY CURRENT (mA) 5.0V OUTPUT -1 3.30 PWM MODE 10 100 MAX8744 toc07 0 LOW-NOISE MODE 3.33 3.27 0 NO-LOAD INPUT SUPPLY CURRENT vs. INPUT VOLTAGE 1 5.0 3.24 0.001 OUTPUT VOLTAGE DEVIATION vs. INPUT VOLTAGE 3.3V OUTPUT 4.0 3.39 50 10 2.0 3.0 LOAD CURRENT (A) 3.3V OUTPUT VOLTAGE vs. LOAD CURRENT 80 60 SKIP MODE PWM MODE 2 0.0 OUTPUT VOLTAGE (V) 20V 3 PWM MODE 10 SKIP MODE EFFICIENCY (%) EFFICIENCY (%) 12V 80 0.01 0.1 1 LOAD CURRENT (A) 90 60 OUTPUT VOLTAGE DEVIATION (%) 0.01 100 MAX8744 toc04 7V 90 0.001 5.00 3.3V OUTPUT EFFICIENCY vs. LOAD CURRENT 100 50 LOW-NOISE MODE 4.90 0.001 1 2 3 LOAD CURRENT (A) 4 5 STANDBY AND SHUTDOWN INPUT CURRENT vs. INPUT VOLTAGE 100 STANDBY (ONx = GND) SUPPLY CURRENT (μA) 0.01 5.05 4.95 MAX8744 toc05 0.001 PWM MODE MAX8744 toc08 50 SKIP MODE OUTPUT VOLTAGE (V) EFFICIENCY (%) EFFICIENCY (%) 12V 80 5.10 MAX8744 toc06 90 SKIP MODE 10 LOW-NOISE MODE MAX8744 toc09 7V MAX8744 toc02 100 MAX8744 toc01 100 5V OUTPUT VOLTAGE vs. LOAD CURRENT MAX8744 toc03 5V OUTPUT EFFICIENCY vs. LOAD CURRENT SHUTDOWN (SHDN = GND) 10 -2 SKIP MODE 1 -3 0 4 8 12 INPUT VOLTAGE (V) 16 20 1 0 4 8 12 INPUT VOLTAGE (V) 16 20 0 4 8 12 INPUT VOLTAGE (V) 16 20 _______________________________________________________________________________________ 9 MAX8744/MAX8745 Typical Operating Characteristics (Circuit of Figure 1, VIN = 12V, SKIP = GND, FSEL = REF, TA = +25°C, unless otherwise noted.) Typical Operating Characteristics (continued) (Circuit of Figure 1, VIN = 12V, SKIP = GND, FSEL = REF, TA = +25°C, unless otherwise noted.) 3.3V SWITCHING FREQUENCY vs. LOAD CURRENT 2 1 LOW-NOISE MODE SKIP = REF 0 4 8 12 INPUT VOLTAGE (V) 16 100 LOW-NOISE SKIP PULSE SKIPPING 10 LDO5 OUTPUT VOLTAGE vs. LOAD CURRENT 0.1 1 20 -10 -6 -2 2 6 2V REF OFFSET VOLTAGE (mV) OUTA OUTPUT VOLTAGE vs. LOAD CURRENT LDO5 POWER-UP 10 MAX8744 toc15 12V A OUTPUT VOLTAGE (V) 5V 4.8 4.7 12.1 2V 1V B 5V 12.0 0 5V C 0 D 11.9 4.5 0 20 40 60 LOAD CURRENT (mA) 80 100 MAX8744 toc12 30 LOAD CURRENT (A) 4.6 10 40 10 MAX8744 toc14 4.9 SAMPLE SIZE = 125 0 0.01 12.2 MAX8744 toc13 5.0 +85°C +25°C 10 1 0.001 20 50 MAX8744 toc11 FORCED-PWM 0 REFERENCE OFFSET VOLTAGE DISTRIBUTION SAMPLE PERCENTAGE (%) IDLE-MODE CURRENT (A) SKIP MODE SKIP = GND 1000 SWITCHING FREQUENCY (kHz) 3 MAX8744 toc10 3.3V IDLE-MODE CURRENT vs. INPUT VOLTAGE OUTPUT VOLTAGE (V) MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers 0 50 100 LOAD CURRENT (mA) 150 1ms/div A. INPUT SUPPLY, 5V/div B. REF, 2V/div SHDN = IN ______________________________________________________________________________________ C. LDO5, 5V/div D. PGOOD5, 5V/div High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers SMPS DELAYED STARTUP SEQUENCE (ON3 = REF) SOFT-START WAVEFORM MAX8744 toc17 MAX8744 toc16 3.3V 0 SMPS DELAYED STARTUP SEQUENCE (ON5 = REF) A 3.3V 0 MAX8744 toc18 A 5V 5V B 0 C 0 12V B 0 0 5A C 0 E 0 A. ON5, 5V/div B. 5V OUTPUT (VOUT5), 5V/div C. PGOOD5, 5V/div ON3 = REF D. AUX LDO OUTPUT (VOUTA), 10V/div E. L5 INDUCTOR CURRENT, 5A/div SMPS SHUTDOWN WAVEFORMS D 0 E 0 1ms/div D. 3.3V OUTPUT (VOUT3), 5V/div E. PGOOD3, 5V/div A. ON3, 5V/div B. 5V OUTPUT (VOUT5), 5V/div C. PGOOD5, 5V/div ON5 = REF A 5V B 0 0 C 3.3V 0 5V D MAX8744 toc21 3A 1A 5.1V A 5.0V B 4.9V 5A B 3.30V 3.25V C 1A 12V 3A 1A C 12V D 0 D 0 20μs/div D. 3.3V OUTPUT (VOUT3), 5V/div E. PGOOD3, 5V/div A 1A 3.35V E 1ms/div D. 3.3V OUTPUT (VOUT3), 5V/div E. PGOOD3, 5V/div OUT3 LOAD TRANSIENT MAX8744 toc20 5A A. SHDN, 5V/div B. 5V OUTPUT (VOUT5), 5V/div C. PGOOD5, 5V/div NO LOAD C 0 OUT5 LOAD TRANSIENT MAX8744 toc19 3.3V 0 B 1ms/div 400μs/div A. ON3 AND ON5, 5V/div B. 5V OUTPUT (VOUT5), 5V/div C. PGOOD5, 5V/div 5V 3.3V D 0 E 0 A 0 3.3V D 3.3V 0 A. IOUT5 = 1A TO 5A, 5A/div B. VOUT5, 50mV/div 20μs/div C. INDUCTOR CURRENT, 5A/div D. LX5, 10V/div A. IOUT3 = 1A TO 3A, 5A/div B. VOUT3, 50mV/div C. INDUCTOR CURRENT, 5A/div D. LX3, 10V/div ______________________________________________________________________________________ 11 MAX8744/MAX8745 Typical Operating Characteristics (continued) (Circuit of Figure 1, VIN = 12V, SKIP = GND, FSEL = REF, TA = +25°C, unless otherwise noted.) MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers Typical Operating Characteristics (continued) (Circuit of Figure 1, VIN = 12V, SKIP = GND, FSEL = REF, TA = +25°C, unless otherwise noted.) OUTPUT OVERVOLTAGE FAULT PROTECTION (MAX8744 ONLY) SKIP TRANSITION OUTPUT UNDERVOLTAGE (SHORT-CIRCUIT) FAULT PROTECTION MAX8744 toc23 MAX8744 toc22 3.3V MAX8744 toc24 5V A 0 A 0 3.35V A 0 3.3V 3.3 B 3.25V 5V B B 0 2A 0 5V C 12V 0 D 0 C 0 12V 5V D D 0 40μs/div A. SKIP, 5V/div B. 3.3V OUTPUT (VOUT3), 100mV/div 0.5A LOAD 0 5V C 0 1ms/div C. INDUCTOR CURRENT, 2A/div D. LX3, 10V/div A.PGOOD3, 5V/div B. 3.3V OUTPUT (VOUT3), 2V/div 20μs/div C. 5V OUTPUT (VOUT5), 5V/div D. DL3, 5V/div A. LOAD FET GATE, 5V/div C. DL3, 5V/div B. 3.3V OUTPUT (VOUT3), 1V/div D. DH3, 10V/div 30mΩ MOSFET LDOHA LOAD TRANSIENT LDOH5 LOAD TRANSIENT MAX8744 toc26 MAX8744 toc25 5V A 0 5.00V A 4.95V 15.0V B 14.5V 100mA B 12.0V C 11.9V 0 20μs/div A. LDO5 OUTPUT, 50mV/div B. LOAD CURRENT, 50mA/div 12 20μs/div A. LOAD FET GATE, 5V/div C. AUX LDO OUTPUT (VOUTA), B. AUX LDO INPUT, 0.5V/div 0.1V/div 0 TO 150mA LOAD TRANSIENT ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers PIN NAME FUNCTION 1 ONA Auxiliary LDO Enable Input. When ONA is pulled low, OUTA is high impedance and the secondary feedback control is disabled. When ONA is driven high, the controller enables the auxiliary LDO. 2 DRVA Auxiliary LDO Transistor Base Driver. Connect DRVA to the base of a pnp power transistor. Add a 680Ω pullup resistor between the base and emitter. ILIM Peak Current-Limit Threshold Adjustment. The current-limit threshold defaults to 50mV if ILIM is pulled up to LDO5. In adjustable mode, the current-limit threshold across CSH_ and CSL_ is precisely 1/10 the voltage seen at ILIM over a 0.5V to 2.0V range. The logic threshold for switchover to the 50mV default value is approximately VLDO5 - 1V. 4 SHDN Shutdown Control Input. The device enters its 8µA supply-current shutdown mode if V SHDN is less than the SHDN input falling edge trip level and does not restart until V SHDN is greater than the SHDN input rising-edge trip level. Connect SHDN to VIN for automatic startup. SHDN can be connected to VIN through a resistive voltage-divider to implement a programmable undervoltage lockout. 5 ON3 3.3V SMPS Enable Input. Driving ON3 high enables the 3.3V SMPS, while pulling ON3 low disables the 3.3V SMPS. If ON3 is connected to REF, the 3.3V SMPS starts after the 5V SMPS reaches regulation (delayed start). Drive ON3 below the clear fault level to reset the fault latch. 6 ON5 5V SMPS Enable Input. Driving ON5 high enables the 5V SMPS, while pulling ON5 low disables the 5V SMPS. If ON5 is connected to REF, the 5V SMPS starts after the 3.3V SMPS reaches regulation (delayed start). Drive ON5 below the clear fault level to reset the fault latch. 7 REF 2.0V Reference Voltage Output. Bypass REF to analog ground with a 0.1µF or greater ceramic capacitor. The reference sources up to 50µA for external loads. Loading REF degrades outputvoltage accuracy according to the REF load-regulation error. The reference shuts down when the system pulls SHDN low. 8 GND Analog Ground. Connect the exposed backside pad to GND. 9 FSEL Frequency Select Input. This three-level logic input sets the controllers’ switching frequency. Connect to LDO5, REF, or GND to select the following typical switching frequencies: LDO5 = 500kHz, REF = 300kHz, GND = 200kHz. 10 SKIP Pulse-Skipping Control Input. Connect to LDO5 for low-noise, forced-PWM operation. Connect to REF for automatic, low-noise, pulse-skipping operation at light loads. Connect to GND for automatic, highefficiency, pulse-skipping operation at light loads. 11 FB5 Feedback Input for the 5V SMPS. Connect to LDO5 for the preset 5V output. In adjustable mode, FB5 regulates to 2V. 12 CSH5 Positive Current-Sense Input for the 5V SMPS. Connect to the positive terminal of the current-sense element. Figure 7 describes two different current-sensing options—using accurate sense resistors or lossless inductor DCR sensing. 13 CSL5 Output-Sense and Negative Current-Sense Input for the 5V SMPS. When using the internal preset 5V feedback-divider (FB5 = LDO5), the controller uses CSL5 to sense the output voltage. Connect to the negative terminal of the current-sense element. CSL5 also serves as the bootstrap input for LDO5. 14 PGOOD5 3 Open-Drain, Power-Good Output for the 5V SMPS. PGOOD5 is pulled low if CSL5 drops more than 10% (typ) below the normal regulation point. PGOOD5 is held low during soft-start and shutdown. PGOOD5 becomes high impedance when CSL5 is in regulation. ______________________________________________________________________________________ 13 MAX8744/MAX8745 Pin Description High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers MAX8744/MAX8745 Pin Description (continued) PIN NAME 15 BST5 16 DH5 High-Side Gate-Driver Output for the 5V SMPS. DH5 swings from LX5 to BST5. LX5 Inductor Connection for the 5V SMPS. Connect LX5 to the switched side of the inductor. LX5 serves as the lower supply rail for the DH5 high-side gate driver. 18 DL5 Low-Side Gate-Driver Output for the 5V SMPS. DL5 swings from PGND to LDO5. 19 PGND Power Ground 20 LDO5 5V Internal Linear-Regulator Output. Bypass with 4.7µF minimum (1µF/25mA). Provides at least 100mA for the DL_ low-side gate drivers, the DH_ high-side drivers through the BST switches, the PWM controller, logic, reference, and external loads. If CSL5 is greater than 4.5V and soft-start is complete, the linear regulator shuts down, and LDO5 connects to CSL5 through a 1Ω switch rated for loads up to 200mA. 21 IN 22 PGOODA 23 DL3 24 LX3 25 DH3 26 BST3 27 PGOOD3 Open-Drain, Power-Good Output for the 3.3V SMPS. PGOOD3 is pulled low if CSL3 drops more than 10% (typ) below the normal regulation point. PGOOD3 is held low during soft-start and shutdown. PGOOD3 becomes high impedance when CSL3 is in regulation. 28 CSL3 Output Sense and Negative Current Sense for the 3.3V SMPS. When using the internal preset 3.3V feedback divider (FB3 = LDO5), the controller uses CSL3 to sense the output voltage. Connect to the negative terminal of the current-sense element. 29 CSH3 Positive Current-Sense Input for the 3.3V SMPS. Connect to the positive terminal of the current-sense element. Figure 7 describes two different current-sensing options—using accurate sense resistors or lossless inductor DCR sensing. 30 FB3 Feedback Input for the 3.3V SMPS. Connect to LDO5 for fixed 3.3V output. In adjustable mode, FB3 regulates to 2V. 17 14 FUNCTION Boost Flying Capacitor Connection for the 5V SMPS. The MAX8744/MAX8745 include an internal boost switch connected between LDO5 and BST5. Connect to an external capacitor as shown in Figure 1. Input of the Startup Circuitry and the LDO5 Internal 5V Linear Regulator. Bypass to PGND with a 0.22µF or greater ceramic capacitor close to the IC. Open-Drain, Power-Good Output for the Auxiliary LDO. PGOODA is pulled low if FBA drops more than 10% (typ) below the normal regulation point, and when the auxiliary LDO is shut down. PGOODA becomes high impedance when FBA is in regulation. Low-Side Gate-Driver Output for the 3.3V SMPS. DL3 swings from PGND to LDO5. Inductor Connection for the 3.3V SMPS. Connect LX3 to the switched side of the inductor. LX3 serves as the lower supply rail for the DH3 high-side gate driver. High-Side Gate-Driver Output for the 3.3V SMPS. DH3 swings from LX3 to BST3. Boost Flying Capacitor Connection for the 3.3V SMPS. The MAX8744/MAX8745 include an internal boost switch connected between LDO5 and BST3. Connect to an external capacitor as shown in Figure 1. ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers PIN NAME 31 FBA 32 OUTA EP EP FUNCTION Auxiliary LDO Feedback Input. Connect a resistive voltage-divider from OUTA to analog ground to adjust the auxiliary linear-regulator output voltage. FBA regulates at 1V. Adjustable Auxiliary Linear-Regulator Output. Bypass OUTA to GND with 1µF or greater capacitor (1µF/25mA). When DRVA < OUTA, the secondary feedback control triggers the DL5 for 1µs forcing the controller to recharge the auxiliary storage capacitor. When DRVA exceeds 25V, the MAX8744/MAX8745 enable a 10mA shunt on OUTA, preventing the storage capacitor from rising to unsafe levels due to the transformer’s leakage inductance. Pulling ONA high enables the linearregulator driver and the secondary feedback control. Exposed Pad. Connect the exposed backside pad to analog ground. Table 1. Component Selection for Standard Applications 300kHz 5V AT 5A 3.3V AT 6A COMPONENT 500kHz 5V AT 3A 3.3V AT 5A INPUT VOLTAGE VIN = 7V TO 24V VIN = 7V TO 24V CIN_, Input Capacitor (3) 10µF, 25V Taiyo Yuden TMK432BJ106KM (3) 10µF, 25V Taiyo Yuden TMK432BJ106KM COUT5, Output Capacitor 2x 100µF, 6V, 35mΩ Sanyo 6TPE100MAZB 2x 100µF, 6V, 35mΩ Sanyo 6TPE100MAZB L5/T5 Inductor/Transformer 6.8µH, 6.4A, 18mΩ (max) 1:2 Sumida 4749-T132 — NH5 High-Side MOSFET Fairchild Semiconductor FDS6612A International Rectifier IRF7807V Fairchild Semiconductor FDS6612A International Rectifier IRF7807V NL5 Low-Side MOSFET Fairchild Semiconductor FDS6670S International Rectifier IRF7807VD1 Fairchild Semiconductor FDS6670S International Rectifier IRF7807VD1 COUT3, Output Capacitor 2x 150µF, 4V, 35mΩ Sanyo 4TPE150MAZB 2x 100µF, 6V, 35mΩ Sanyo 6TPE100MAZB L3, Inductor 5.7µH, 9A, 8.5mΩ TDK RLF12560T-5R6N9R2 3.9µH, 6.5A, 15mΩ Sumida CDRH124-3R9NC NH3 High-Side MOSFET Fairchild Semiconductor FDS6612A International Rectifier IRF7807V Fairchild Semiconductor FDS6612A International Rectifier IRF7807V NL3 Low-Side MOSFET Fairchild Semiconductor FDS6670S International Rectifier IRF7807VD1 Fairchild Semiconductor FDS6670S International Rectifier IRF7807VD1 5V OUTPUT 3V OUTPUT ______________________________________________________________________________________ 15 MAX8744/MAX8745 Pin Description (continued) MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers CIN INPUT (VIN) CIN IN 21 D1 NH1 25 26 CBST1 0.1μF L1 3.3V PWM OUTPUT COUT1 R1 5.62kΩ R2 3.92kΩ 24 23 DL1 DH3 DH5 BST3 BST5 LX3 LX5 DL5 DL3 NL1 28 CSH3 CSH5 CSL3 CSL5 C3 1000pF ILIM REF (300kHz) 9 7 FSEL FB5 REF FB3 CREF 0.22μF LDO5 SECONDARY OUTPUT 2 32 CLDOA 4.7μF T1 CBST2 0.1μF 17 5V PWM OUTPUT 18 NL2 DL2 12 R3 10.5kΩ R4 4.02kΩ 13 C2 0.22μF 3 C4 1000pF COUT2 11 30 20 CLDO5 4.7μF 5V LDO OUTPUT DRVA SKIP 10 OUTA R5 110kΩ 31 CONNECT TO 5V OR 3.3V FBA R7 100kΩ R6 10kΩ PGOODA PGOOD3 4 5 ON OFF 6 1 SHDN PGOOD5 R8 100kΩ R9 100kΩ 22 27 POWER-GOOD 14 ON3 ON5 ONA POWER GROUND ANALOG GROUND SEE TABLE 1 FOR COMPONENT SPECIFICATIONS. Figure 1. Standard Application Circuit 16 SECONDARY OUTPUT MAX8744 MAX8745 R10 680Ω 12V LDO OUTPUT CAUX 4.7μF 15 19 PGND 8 GND 29 C1 0.22μF NH2 16 ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers SUPPLIER WEBSITE AVX www.avx.com Central Semiconductor Fairchild www.centralsemi.com International Rectifier www.irf.com www.fairchildsemi.com Kemet www.kemet.com NEC/Tokin www.nec-tokin.com Panasonic www.panasonic.com/industrial Phillips www.phillips.com Pulse www.pulseeng.com Renesas www.renesas.com Sanyo www.secc.co.jp Sumida www.sumida.com Taiyo Yuden www.t-yuden.com TDK www.component.tdk.com TOKO www.tokoam.com Vishay (Dale, Siliconix) www.vishay.com Detailed Description The MAX8744/MAX8745 standard application circuit (Figure 1) generates the 5V/5A and 3.3V/5A typical of the main supplies in a notebook computer. The input supply range is 7V to 24V. See Table 1 for component selections, while Table 2 lists the component manufacturers. The MAX8744/MAX8745 contain two interleaved, fixedfrequency, step-down controllers designed for low-voltage power supplies. The optimal interleaved architecture guarantees out-of-phase operation, reducing the input capacitor ripple. One internal LDO generates the keepalive 5V power. The MAX8744/MAX8745 have an auxiliary LDO with an adjustable output for generating either the 3.3V keep-alive supply or regulating the low-power 12V system supply. Fixed 5V Linear Regulator (LDO5) An internal linear regulator produces a preset 5V lowcurrent output. LDO5 powers the gate drivers for the external MOSFETs, and provides the bias supply required for the SMPS analog controller, reference, and logic blocks. LDO5 supplies at least 100mA for external and internal loads, including the MOSFET gate drive, which typically varies from 5mA to 50mA, depending on the switching frequency and external MOSFETs selected. Bypass LDO5 with a 4.7µF or greater ceramic capacitor (1µF per 25mA of load) to guarantee stability under the full-load conditions. The MAX8744/MAX8745 switch-mode power supplies (SMPS) require a 5V bias supply in addition to the highpower input supply (battery or AC adapter). This 5V bias supply is generated by the controller’s internal 5V linear regulator (LDO5). This bootstrapped LDO allows the controller to power up independently. The gate-driver input supply is connected to the fixed 5V linear-regulator output (LDO5). Therefore, the 5V LDO supply must provide LDO5 (PWM controller) and the gate-drive power, so the maximum supply current required is: IBIAS = ICC + fSW (QG(LOW) + QG(HIGH)) = 5mA to 50mA (typ) where ICC is 0.7mA (typ), fSW is the switching frequency, and Q G(LOW) and Q G(HIGH) are the MOSFET data sheet’s total gate-charge specification limits at VGS = 5V. SMPS to LDO Bootstrap Switchover When the 5V main output voltage is above the LDO5 bootstrap-switchover threshold and has completed soft-start, an internal 1Ω (typ) p-channel MOSFET shorts CSL5 to LDO5, while simultaneously shutting down the LDO5 linear regulator. This bootstraps the device, powering the internal circuitry and external loads from the 5V SMPS output (CSL5), rather than through the linear regulator from the battery. Bootstrapping reduces power dissipation due to gate charge and quiescent losses by providing power from a 90%-efficient switch-mode source, rather than from a much-less-efficient linear regulator. The current capability increases from 100mA to 200mA when the LDO5 output is switched over to CSL5. When ON5 is pulled low, the controller immediately disables the bootstrap switch and reenables the 5V LDO. Reference (REF) The 2V reference is accurate to ±1% over temperature and load, making REF useful as a precision system reference. Bypass REF to GND with a 0.1µF or greater ceramic capacitor. The reference sources up to 50µA and sinks 5µA to support external loads. If highly accurate specifications are required for the main SMPS output voltages, the reference should not be loaded. Loading the reference reduces the LDO5, CSL5 (OUT5), CSL3 (OUT3), and OUTA output voltages slightly because of the reference load-regulation error. System Enable/Shutdown (SHDN) Drive SHDN below the precise SHDN input falling-edge trip level to place the MAX8744/MAX8745 in its lowpower shutdown state. The controller consumes only 8µA of quiescent current while in shutdown mode. When shutdown mode activates, the reference turns off after the controller completes the shutdown sequence ______________________________________________________________________________________ 17 MAX8744/MAX8745 Table 2. Component Suppliers MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers IN FSEL SHDN 5V LINEAR REGULATOR OSC LDO5 LDO BYPASS CIRCUITRY ILIM SKIP CSH5 CSL5 CSH3 CSL3 LDO5 BST3 PWM5 CONTROLLER (FIGURE 3) PWM3 CONTROLLER (FIGURE 3) DH3 LX3 BST5 DH5 LX5 LDO5 DL5 LDO5 DL3 PGND FB3 ON5 FB DECODE (FIGURE 5) FB DECODE INTERNAL (FIGURE 5) FB FB5 ON3 REF PGOODA POWER-GOOD AND FAULT PROTECTION (FIGURE 6) R SECONDARY FEEDBACK PGOOD3 FAULT PGOOD5 2.0V REF GND R DRVA AUXILIARY LINEAR REGULATOR OUTA FBA ONA MAX8744 MAX8745 Figure 2. Functional Diagram 18 ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers INPUTS* MODE OUTPUTS SHDN ON5 ON3 Shutdown Mode Low X X OFF OFF OFF Standby Mode High Low Low ON OFF OFF Normal Operation High High High ON ON ON 3.3V SMPS Active High Low High ON OFF ON 5V SMPS Active High High Low OFF LDO5 to CSL5 bypass switch enabled ON OFF Normal Operation (Delayed 5V SMPS Startup) High Ref High OFF LDO5 to CSL5 bypass switch enabled ON Power-up after 3.3V SMPS is in regulation ON Normal Operation (Delayed 3.3V SMPS Startup) High High Ref OFF LDO5 to CSL5 bypass switch enabled ON ON Power-up after 5V SMPS is in regulation LDO5 5V SMPS 3V SMPS *SHDN is an accurate, low-voltage logic input with 1V falling-edge threshold voltage and 1.6V rising-edge threshold voltage. ON3 and ON5 are tri-level CMOS logic inputs, a logic-low voltage is less than 0.8V, a logic-high voltage is greater than 2.4V, and the middle-logic level is between 1.7V and 2.3V (see the Electrical Characteristics table). making the threshold to exit shutdown less accurate. To guarantee startup, drive SHDN above 2V (SHDN input rising-edge trip level). For automatic shutdown and startup, connect SHDN to VIN. The accurate 1V fallingedge threshold on SHDN can be used to detect a specific input voltage level and shut the device down. Once in shutdown, the 1.6V rising-edge threshold activates, providing sufficient hysteresis for most applications. reach their nominal regulation voltage 2ms after the SMPS controllers are enabled (see the Soft-Start Waveforms in the Typical Operating Characteristics). This gradual slew rate effectively reduces the input surge current by minimizing the current required to charge the output capacitors (IOUT = ILOAD + COUT VOUT(NOM) / tSLEW). SMPS POR, UVLO, and Soft-Start ON3 and ON5 control SMPS power-up sequencing. ON3 or ON5 rising above 2.4V enables the respective outputs. ON3 or ON5 falling below 1.6V disables the respective outputs. Driving ON_ below 0.8V clears the overvoltage, undervoltage, and thermal fault latches. Power-on reset (POR) occurs when LDO5 rises above approximately 1V, resetting the undervoltage, overvoltage, and thermal-shutdown fault latches. The POR circuit also ensures that the low-side drivers are pulled high until the SMPS controllers are activated. Figure 2 is the MAX8744/MAX8745 block diagram. The LDO5 input undervoltage-lockout (UVLO) circuitry inhibits switching if the 5V bias supply (LDO5) is below its 4V UVLO threshold. Once the 5V bias supply (LDO5) rises above this input UVLO threshold and the SMPS controllers are enabled (ON_ driven high), the SMPS controllers start switching, and the output voltages begin to ramp up using soft-start. If the LDO5 voltage drops below the UVLO threshold, the controller stops switching and pulls the low-side gate drivers low until the LDO5 voltage recovers or drops below the POR threshold. The internal soft-start gradually increases the feedback voltage with a 1V/ms slew rate. Therefore, the outputs SMPS Enable Controls (ON3, ON5) SMPS Power-Up Sequencing Connecting ON3 or ON5 to REF forces the respective outputs off while the other output is below regulation and starts after that output regulates. The second SMPS remains on until the first SMPS turns off, the device shuts down, a fault occurs, or LDO5 goes into UVLO. Both supplies begin their power-down sequence immediately when the first supply turns off. Output Discharge (Soft-Shutdown) When the switching regulators are disabled—when ON_ or SHDN is pulled low, or when an output undervoltage fault occurs—the internal soft-shutdown gradually decreases the feedback voltage with a 0.5V/ms slew rate. Therefore, the regulation voltage drops to 0V with- ______________________________________________________________________________________ 19 MAX8744/MAX8745 Table 3. Operating Mode Truth Table MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers FROM FB (SEE FIGURE 5) REF SOFTSTART/STOP SLOPE COMP ON_ SKIP OSC AGND FSEL TRI-LEVEL DECODE R Q DH DRIVER S 0.2 x VLIMIT 0.1 x VLIMIT IDLE MODE CURRENT ILIM A = 1/10 PEAK CURRENT LIMIT A = 1.2 NEG CURRENT LIMIT CSL_ S Q CSH_ R DL DRIVER ZERO CROSSING PGND DRVA ONE-SHOT OUTA 5V SMPS ONLY Figure 3. PWM Controller Functional Diagram in 4ms after the SMPS controllers are disabled (see the soft-shutdown waveforms in the Typical Operating Characteristics). This slowly discharges the output capacitance, eliminating the negative output voltages caused by quickly discharging the output through the inductor and low-side MOSFET. When an SMPS target 20 voltage discharges to 0.1V, its low-side driver (DL_) is forced high, clamping the respective SMPS output to GND. The reference remains active to provide an accurate threshold and to provide overvoltage protection. Both SMPS controllers contain separate soft-shutdown circuits. ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers FSEL SWITCHING FREQUENCY (kHz) LDO5 500 REF 300 GND 200 Fixed-Frequency, Current-Mode PWM Controller The heart of each current-mode PWM controller is a multi-input, open-loop comparator that sums two signals: the output-voltage error signal with respect to the reference voltage and the slope-compensation ramp (Figure 3). The MAX8744/MAX8745 use a direct-summing configuration, approaching ideal cycle-to-cycle control over the output voltage without a traditional error amplifier and the phase shift associated with it. Frequency Selection (FSEL) The FSEL input selects the PWM mode switching frequency. Table 4 shows the switching frequency based on FSEL connection. High-frequency (500kHz) operation optimizes the application for the smallest component size, trading off efficiency due to higher switching losses. This may be acceptable in ultraportable devices where the load currents are lower. Low-frequency (200kHz) operation offers the best overall efficiency at the expense of component size and board space. Forced-PWM Mode The low-noise forced-PWM mode (SKIP = LDO5) disables the zero-crossing comparator, which controls the low-side switch on-time. This forces the low-side gatedrive waveform to be constantly the complement of the high-side gate-drive waveform, so the inductor current reverses at light loads while DH_ maintains a duty factor of VOUT/VIN. The benefit of forced-PWM mode is to keep the switching frequency fairly constant. However, forcedPWM operation comes at a cost: the no-load 5V supply current remains between 20mA to 50mA, depending on the external MOSFETs and switching frequency. Forced-PWM mode is most useful for avoiding audiofrequency noise and improving load-transient response. Since forced-PWM operation disables the zero-crossing comparator, the inductor current reverses under light loads. Light-Load Operation Control (SKIP) The MAX8744/MAX8745 include a light-load operating mode control input (SKIP) used to enable or disable the zero-crossing comparator for both switching regulators. When the zero-crossing comparator is enabled, the regulator forces DL_ low when the current-sense inputs detect zero inductor current. This keeps the inductor from discharging the output capacitors and forces the regulator to skip pulses under light-load conditions to avoid overcharging the output. When the zero-crossing comparator is disabled, the regulator is forced to maintain PWM operation under light-load conditions (forced-PWM). Idle Mode Current-Sense Threshold When pulse-skipping mode is enabled, the on-time of the step-down controller terminates when the output voltage exceeds the feedback threshold and when the currentsense voltage exceeds the Idle Mode current-sense threshold. Under light-load conditions, the on-time duration depends solely on the Idle Mode current-sense threshold, which is 20% (SKIP = GND) of the full-load current-limit threshold set by ILIM, or the low-noise current-sense threshold, which is 10% (SKIP = REF) of the full-load current-limit threshold set by ILIM. This forces the controller to source a minimum amount of power with each cycle. To avoid overcharging the output, another on-time cannot begin until the output voltage drops below the feedback threshold. Since the zero-crossing comparator prevents the switching regulator from sinking current, the controller must skip pulses. Therefore, the controller regulates the valley of the output ripple under light-load conditions. Automatic Pulse-Skipping Crossover In skip mode, an inherent automatic switchover to PFM takes place at light loads (Figure 4). This switchover is affected by a comparator that truncates the low-side switch on-time at the inductor current’s zero crossing. The zero-crossing comparator senses the inductor current across CSH_ to CSL_. Once VCSH_ - VCSL_ drops below the 3mV zero-crossing, current-sense threshold, the comparator forces DL_ low (Figure 3). This mechanism causes the threshold between pulse-skipping PFM and nonskipping PWM operation to coincide with the boundary between continuous and discontinuous inductor-current operation (also known as the “critical conduction” point). The load-current level at which PFM/PWM crossover occurs, ILOAD(SKIP), is given by: ILOAD(SKIP) = (VIN − VOUT )VOUT 2VINfOSCL The switching waveforms may appear noisy and asynchronous when light loading causes pulse-skipping operation, but this is a normal operating condition that results in high light-load efficiency. Trade-offs in PFM noise vs. light-load efficiency are made by varying the inductor value. Generally, low inductor values produce ______________________________________________________________________________________ 21 MAX8744/MAX8745 Table 4. FSEL Configuration Table a broader efficiency vs. load curve, while higher values result in higher full-load efficiency (assuming that the coil resistance remains fixed) and less output-voltage ripple. Penalties for using higher inductor values include larger physical size and degraded load-transient response (especially at low input-voltage levels). Output Voltage DC output accuracy specifications in the Electrical Characteristics table refer to the error comparator’s threshold. When the inductor continuously conducts, the MAX8744/MAX8745 regulate the peak of the output ripple, so the actual DC output voltage is lower than the slope-compensated trip level by 50% of the output ripple voltage. For PWM operation (continuous conduction), the output voltage is accurately defined by the following equation: ⎛ A ⎞ ⎛V V ⎞ VOUT(PWM) = VNOM ⎜1− SLOPE RIPPLE ⎟ − ⎜ RIPPLE ⎟ ⎠ 2 VIN ⎝ ⎠ ⎝ where V NOM is the nominal output voltage, A SLOPE equals 1%, and VRIPPLE is the output ripple voltage (V RIPPLE = ESR x ΔI INDUCTOR, as described in the Output Capacitor Selection section). In discontinuous conduction (IOUT < ILOAD(SKIP)), the MAX8744/MAX8745 regulate the valley of the output ripple, so the output voltage has a DC regulation level higher than the error-comparator threshold. For PFM operation (discontinuous conduction), the output voltage is approximately defined by the following equation: VOUT(PFM) = VNOM + 1 ⎛ fSW ⎞ IIDLEESR 2 ⎜⎝ fOSC ⎟⎠ where VNOM is the nominal output voltage, fOSC is the maximum switching frequency set by the internal oscillator, fSW is the actual switching frequency, and IIDLE is the Idle Mode inductor current when pulse skipping. Connect FB3 and FB5 to LDO5 to enable the fixed SMPS output voltages (3.3V and 5V, respectively), set by a preset, internal resistive voltage-divider connected between the output (CSL_) and analog ground. Connect a resistive voltage-divider at FB_ between the output (CSL_) and GND to adjust the respective output voltage between 2V and 5.5V (Figure 5). Choose RFBLO (resistance from FB to AGND) to be approximately 10kΩ and solve for RFBHI (resistance from the output to FB) using the equation: ⎛ VOUT _ ⎞ RFBHI = RFBLO ⎜ −1⎟ ⎝ VFB _ ⎠ where VFB_ = 2V nominal. When adjusting both output voltages, set the 3.3V SMPS lower than the 5V SMPS. LDO5 connects to the TO ERROR AMPLIFIER ADJUSTABLE OUTPUT FB tON(SKIP) = LDO5 VOUT VINfOSC INDUCTOR CURRENT MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers R 9R IPK ILOAD = IPK / 2 OUT 0 FIXED OUTPUT FB = LDO5 TIME ON-TIME Figure 4. Pulse-Skipping/Discontinuous Crossover Point 22 Figure 5. Dual Mode Feedback Decoder ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers Current-Limit Protection (ILIM) The current-limit circuit uses differential current-sense inputs (CSH_ and CSL_) to limit the peak inductor current. If the magnitude of the current-sense signal exceeds the current-limit threshold, the PWM controller turns off the high-side MOSFET (Figure 3). The actual maximum load current is less than the peak currentlimit threshold by an amount equal to half of the inductor ripple current. Therefore, the maximum load capability is a function of the current-sense resistance, inductor value, switching frequency, and duty cycle (VOUT/VIN). In forced-PWM mode, the MAX8744/MAX8745 also implement a negative current limit to prevent excessive reverse inductor currents when VOUT is sinking current. The negative current-limit threshold is set to approximately 120% of the positive current limit and tracks the positive current limit when ILIM is adjusted. Connect ILIM to LDO5 for the 50mV default threshold, or adjust the current-limit threshold with an external resistor-divider at ILIM. Use a 2µA to 20µA divider current for accuracy and noise immunity. The current-limit threshold adjustment range is from 50mV to 200mV. In the adjustable mode, the current-limit threshold voltage equals precisely 1/10 the voltage seen at ILIM. The logic threshold for switchover to the default value is approximately VLDO5 - 1V. MOSFET Gate Drivers (DH_, DL_) The DH_ and DL_ drivers are optimized for driving moderate-sized high-side and larger low-side power MOSFETs. This is consistent with the low duty factor seen in notebook applications, where a large V IN V OUT differential exists. The high-side gate drivers (DH_) source and sink 2A, and the low-side gate drivers (DL_) source 1.7A and sink 3.3A. This ensures robust gate drive for high-current applications. The DH_ floating high-side MOSFET drivers are powered by charge pumps at BST_ while the DL_ synchronous-rectifier drivers are powered directly by the fixed 5V linear regulator (LDO5). Adaptive dead-time circuits monitor the DL_ and DH_ drivers and prevent either FET from turning on until the other is fully off. The adaptive driver dead-time allows operation without shoot-through with a wide range of MOSFETs, minimizing delays and maintaining efficiency. There must be a low-resistance, low-inductance path from the DL_ and DH_ drivers to the MOSFET gates for the adaptive dead-time circuits to work properly; otherwise, the sense circuitry in the MAX8744/ MAX8745 interprets the MOSFET gates as “off” while charge actually remains. Use very short, wide traces (50 mils to 100 mils wide if the MOSFET is in from the driver). The internal pulldown transistor that drives DL_ low is robust, with a 0.6Ω (typ) on-resistance. This helps prevent DL_ from being pulled up due to capacitive coupling from the drain to the gate of the low-side MOSFETs when the inductor node (LX_) quickly switches from ground to VIN. FAULT PROTECTION POWER GOOD 0.9 x INT REF_ 0.7 x INT REF_ 1.11 x INT REF_ INTERNAL FB Carefully observe the PC board layout guidelines to ensure that noise and DC errors do not corrupt the differential current-sense signals seen by CSH_ and CSL_. Place the IC close to the sense resistor with short, direct traces, making a Kelvin-sense connection to the current-sense resistor. ENABLE OVP ENABLE UVP 6144 CLK FAULT LATCH FAULT POWER-GOOD POR Figure 6. Power-Good and Fault Protection ______________________________________________________________________________________ 23 MAX8744/MAX8745 5V output (CSL5) through an internal switch only when CSL5 is above the LDO5 bootstrap threshold (4.5V) and the soft-start sequence for the CSL5 side has completed. Bootstrapping works most effectively when the fixed output voltages are used. Once LDO5 is bootstrapped from CSL5, the internal 5V linear regulator turns off. This reduces the internal power dissipation and improves efficiency at higher input voltages. MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers Table 5. Operating Modes Truth Table MODE CONDITION COMMENT Power-Up LDO5 < UVLO threshold Transitions to discharge mode after VIN POR and after REF becomes valid. LDO5, REF remain active. DL_ is active (high). Run SHDN = high, ON3 or ON5 enabled Normal operation. Output Overvoltage (OVP) Protection (MAX8744) Either output > 111% of nominal level Exited by POR or cycling SHDN, ON3, or ON5. Output Undervoltage Protection (UVP) Either output < 70% of nominal level, UVP is enabled 6144 clock cycles (1/fOSC) after the output is enabled Exited by POR or cycling SHDN, ON3, or ON5. Standby ON5 and ON3 < startup threshold, SHDN = high DL_ stays high. LDO5 active. Shutdown SHDN = low All circuitry off. Thermal Shutdown TJ > +160°C Exited by POR or cycling SHDN, ON3, or ON5. DL3 and DL5 go high before LDO5 turns off. They remain high as long as possible thereafter. Switchover Fault Excessive current on LDO5 switchover transistors Exited by POR or cycling SHDN, ON3, or ON5. Applications with high input voltages and long inductive driver traces may require additional gate-to-source capacitance to ensure fast-rising LX_ edges do not pull up the low-side MOSFETs gate, causing shoot-through currents. The capacitive coupling between LX_ and DL_ created by the MOSFET’s gate-to-drain capacitance (CGD = CRSS), gate-to-source capacitance (CGS = CISS - C GD ), and additional board parasitics should not exceed the following minimum threshold. ⎛C ⎞ VGS(TH) > VIN ⎜ RSS ⎟ ⎝ CISS ⎠ Lot-to-lot variation of the threshold voltage may cause problems in marginal designs. Power-Good Output (PGOOD_) PGOOD_ is the open-drain output of a comparator that continuously monitors both SMPS output voltages and the auxiliary LDO output for undervoltage conditions. PGOOD_ is actively held low in shutdown (SHDN = GND), standby (ON3 = ON5 = ONA = GND), soft-start, and soft-shutdown. Once the soft-start sequence terminates, PGOOD_ becomes high impedance as long as the outputs are above 90% of the nominal regulation voltage set by FB_. PGOOD_ goes low once the respective output drops 10% below its nominal regulation point, an 24 SMPS output overvoltage fault occurs, or ON_ or SHDN is low. For a logic-level PGOOD_ output voltage, connect an external pullup resistor between PGOOD_ and LDO5. A 100kΩ pullup resistor works well in most applications. Fault Protection Output Overvoltage Protection (OVP)— MAX8744 Only If the output voltage of either SMPS rises above 111% of its nominal regulation voltage and the OVP protection is enabled, the controller sets the fault latch, pulls PGOOD low, shuts down the SMPS controllers that tripped the fault, and immediately pulls DH_ low and forces DL_ high. This turns on the synchronous-rectifier MOSFETs with 100% duty, rapidly discharging the output capacitors and clamping both outputs to ground. However, immediately latching DL_ high typically causes slightly negative output voltages due to the energy stored in the output LC at the instant the OVP occurs. If the load cannot tolerate a negative voltage, place a power Schottky diode across the output to act as a reverse-polarity clamp. If the condition that caused the overvoltage persists (such as a shorted high-side MOSFET), the battery blows. The other output is shut down using the soft-shutdown sequence. Cycle LDO5 below 1V or toggle either ON3, ON5, or SHDN to clear the fault latch and restart the SMPS controllers. ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers Thermal Fault Protection The MAX8744/MAX8745 feature a thermal fault-protection circuit. When the junction temperature rises above +160°C, a thermal sensor activates the fault latch, pulls PGOOD low, and shuts down both SMPS controllers using the soft-shutdown sequence. When an SMPS output voltage drops to 0.1V, its synchronous rectifier turns on, clamping the discharged output to GND. Toggle either ON3, ON5, or SHDN to clear the fault latch and restart the controllers after the junction temperature cools by 15°C. Auxiliary LDO Detailed Description The MAX8744/MAX8745 include an auxiliary linear regulator (OUTA) that can be configured for 12V, ideal for PCMCIA power requirements, and for biasing the gates of load switches in a portable device. OUTA can also be configured for outputs from 1V to 23V. The auxiliary regulator has an independent ON/OFF control, allowing it to be shut down when not needed, reducing power consumption when the system is in a low-power state. A flyback-winding control loop regulates a secondary winding output, improving cross-regulation when the primary output is lightly loaded or when there is a low inputoutput differential voltage. If VDRVA - VOUTD, the low-side switch is turned on for a time equal to 33% of the switching period. This reverses the inductor (primary) current, pulling current from the output filter capacitor and causing the flyback transformer to operate in forward mode. The low impedance presented by the transformer secondary in forward mode dumps current into the secondary output, charging up the secondary capacitor and bringing VINA - VOUTA back into regulation. The secondary feedback loop does not improve secondary output accuracy in normal flyback mode, where the main (primary) output is heavily loaded. In this condition, secondary output accuracy is determined by the secondary rectifier drop, transformer turns ratio, and accuracy of the main output voltage. SMPS Design Procedure Firmly establish the input voltage range and maximum load current before choosing a switching frequency and inductor operating point (ripple-current ratio). The primary design trade-off lies in choosing a good switching frequency and inductor operating point, and the following four factors dictate the rest of the design: • Input Voltage Range. The maximum value (VIN(MAX)) must accommodate the worst-case, high AC-adapter voltage. The minimum value (VIN(MIN)) must account for the lowest battery voltage after drops due to connectors, fuses, and battery selector switches. If there is a choice at all, lower input voltages result in better efficiency. • Maximum Load Current. There are two values to consider. The peak load current (I LOAD(MAX) ) determines the instantaneous component stresses and filtering requirements and thus drives output capacitor selection, inductor saturation rating, and the design of the current-limit circuit. The continuous load current (ILOAD) determines the thermal stresses and thus drives the selection of input capacitors, MOSFETs, and other critical heat-contributing components. • Switching Frequency. This choice determines the basic trade-off between size and efficiency. The optimal frequency is largely a function of maximum input voltage, due to MOSFET switching losses that are proportional to frequency and VIN2. The optimum frequency is also a moving target, due to rapid improvements in MOSFET technology that are making higher frequencies more practical. • Inductor Operating Point. This choice provides trade-offs between size vs. efficiency and transient response vs. output ripple. Low inductor values provide better transient response and smaller physical size, but also result in lower efficiency and higher output ripple due to increased ripple currents. The minimum practical inductor value is one that causes the circuit to operate at the edge of critical conduction (where the inductor current just touches zero with every cycle at maximum load). Inductor values lower than this grant no further size-reduction benefit. The optimum operating point is usually found between 20% and 50% ripple current. When pulse skipping (SKIP low and light loads), the inductor value also determines the load-current value at which PFM/PWM switchover occurs. Inductor Selection The switching frequency and inductor operating point determine the inductor value as follows: ______________________________________________________________________________________ 25 MAX8744/MAX8745 Output Undervoltage Protection (UVP) Each SMPS controller includes an output UVP protection circuit that begins to monitor the output 6144 clock cycles (1/fOSC) after that output is enabled (ON_ pulled high). If either SMPS output voltage drops below 70% of its nominal regulation voltage and the UVP protection is enabled, the UVP circuit sets the fault latch, pulls PGOOD low, and shuts down both controllers using the soft-shutdown sequence. When an SMPS output voltage drops to 0.1V, its synchronous rectifier turns on, clamping the discharged output to GND. Cycle LDO5 below 1V or toggle either ON3, ON5, or SHDN to clear the fault latch and restart the SMPS controllers. MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers L= VOUT (VIN − VOUT ) VINfOSCILOAD(MAX)LIR For example: ILOAD(MAX) = 5A, VIN = 12V, VOUT = 5V, fOSC = 300kHz, 30% ripple current or LIR = 0.3: L= 5V x (12V − 5V ) 12V x 300kHz x 5A x 0.3 = 6.50μH Find a low-loss inductor having the lowest possible DC resistance that fits in the allotted dimensions. Most inductor manufacturers provide inductors in standard values, such as 1.0µH, 1.5µH, 2.2µH, 3.3µH, etc. Also look for non-standard values, which can provide a better compromise in LIR across the input voltage range. If using a swinging inductor (where the no-load inductance decreases linearly with increasing current), evaluate the LIR with properly scaled inductance values. For the selected inductance value, the actual peak-to-peak inductor ripple current (ΔIINDUCTOR) is defined by: V (V − VOUT ) ΔIINDUCTOR = OUT IN VINfOSCL Ferrite cores are often the best choice, although powdered iron is inexpensive and can work well at 200kHz. The core must be large enough not to saturate at the peak inductor current (IPEAK): I PEAK = I LOAD(MAX) + ΔIINDUCTOR 2 Transformer Design (for MAX8744/MAX8745 Auxiliary Output) A coupled inductor or transformer can be substituted for the inductor in the 5V SMPS to create an auxiliary output (Figure 1). The MAX8744/MAX8745 is particularly well suited for such applications because the secondary feedback threshold automatically triggers DL5 even if the 5V output is lightly loaded. The power requirements of the auxiliary supply must be considered in the design of the main output. The transformer must be designed to deliver the required current in both the primary and the secondary outputs with the proper turns ratio and inductance. The power ratings of the synchronous-rectifier MOSFETs and the current limit in the MAX8744/MAX8745 must also be adjusted accordingly. Extremes of low input-output differentials, 26 widely different output loading levels, and high turns ratios can further complicate the design due to parasitic transformer parameters such as interwinding capacitance, secondary resistance, and leakage inductance. Power from the main and secondary outputs is combined to get an equivalent current referred to the main output. Use this total current to determine the current limit (see the Setting the Current Limit section): ITOTAL = PTOTAL / VOUT5 where ITOTAL is the equivalent output current referred to the main output, and PTOTAL is the sum of the output power from both the main output and the secondary output: N= VSEC + VFWD VOUT5 + VRECT + VSENSE where LPRIMARY is the primary inductance, N is the transformer turns ratio, VSEC is the minimum required rectified secondary voltage, VFWD is the forward drop across the secondary rectifier, VOUT5(MIN) is the minimum value of the main output voltage, and VRECT is the on-state voltage drop across the synchronous-rectifier MOSFET. The transformer secondary return is often connected to the main output voltage instead of ground in order to reduce the necessary turns ratio. In this case, subtract VOUT5 from the secondary voltage (VSEC VOUT5) in the transformer turns-ratio equation above. The secondary diode in coupled-inductor applications must withstand flyback voltages greater than 60V. Common silicon rectifiers, such as the 1N4001, are also prohibited because they are too slow. Fast silicon rectifiers such as the MURS120 are the only choice. The flyback voltage across the rectifier is related to the VIN VOUT difference, according to the transformer turns ratio: VFLYBACK = VSEC + (VIN – VOUT5) x N where N is the transformer turns ratio (secondary windings/primary windings), and VSEC is the maximum secondary DC output voltage. If the secondary winding is returned to VOUT5 instead of ground, subtract VOUT5 from V FLYBACK in the equation above. The diode’s reverse breakdown voltage rating must also accommodate any ringing due to leakage inductance. The diode’s current rating should be at least twice the DC load current on the secondary output. Transient Response The inductor ripple current also impacts transientresponse performance, especially at low VIN - VOUT differentials. Low inductor values allow the inductor ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers MAX8744/MAX8745 INPUT (VIN) CIN MAX8744 MAX8745 DH_ SENSE RESISTOR NH L LESL RSENSE LX_ DL_ NL DL R1 CEQ COUT L CEQR1 = SENSE RSENSE PGND CSH_ CSL_ A) OUTPUT SERIES RESISTOR SENSING INPUT (VIN) CIN MAX8744 MAX8745 DH_ INDUCTOR NH L RDCR RCS = LX_ DL_ NL PGND COUT DL R1 R2 RDCR = ( R1R2+ R2) R L CEQ DCR [R11 + R21 ] CEQ CSH_ CSL_ B) LOSSLESS INDUCTOR SENSING Figure 7. Current-Sense Configurations ______________________________________________________________________________________ 27 MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers current to slew faster, replenishing charge removed from the output filter capacitors by a sudden load step. The total output voltage sag is the sum of the voltage sag while the inductor is ramping up, and the voltage sag before the next pulse can occur: VSAG = ( L ΔILOAD(MAX) ( ) V VILIM RCS = LIMIT = 10 x ILIMIT ILIMIT 2 2COUT VIN x DMAX − VOUT ΔILOAD(MAX) (T − ΔT) ) + COUT where DMAX is maximum duty factor (see the Electrical Characteristics), T is the switching period (1 / fOSC), and ΔT equals VOUT/ VIN x T when in PWM mode, or L x 0.2 x IMAX / (VIN - VOUT) when in skip mode. The amount of overshoot during a full-load to no-load transient due to stored inductor energy can be calculated as: VSOAR tighter accuracy, but also dissipate more power. Most applications employ a current-limit threshold (VLIMIT) of 50mV to 100mV, so the sense resistor may be determined by: For the best current-sense accuracy and overcurrent protection, use a 1% tolerance current-sense resistor between the inductor and output as shown in Figure 7A. This configuration constantly monitors the inductor current, allowing accurate current-limit protection. However, the parasitic inductance of the current-sense resistor can cause current-limit inaccuracies, especially when using low-value inductors and current-sense resistors. This parasitic inductance (LSENSE) can be canceled by adding an RC circuit across the sense resistor with an equivalent time constant: 2 ΔILOAD(MAX) ) L ( ≈ L CEQR1 = SENSE RSENSE 2COUT VOUT Setting the Current Limit The minimum current-limit threshold must be great enough to support the maximum load current when the current limit is at the minimum tolerance value. The peak inductor current occurs at ILOAD(MAX) plus half the ripple current; therefore: Alternatively, high-power applications that do not require highly accurate current-limit protection may reduce the overall power dissipation by connecting a series RC circuit across the inductor (Figure 7B) with an equivalent time constant: ⎛ R2 ⎞ RCS = ⎜ ⎟ RDCR ⎝ R1 + R2 ⎠ ILIMIT > ILOAD(MAX) + ⎛⎜ ΔIINDUCTOR ⎞⎟ ⎝ 2 ⎠ and: where ILIMIT_ equals the minimum current-limit threshold voltage divided by the current-sense resistance (RSENSE_). For the default setting, the minimum currentlimit threshold is 45mV. Connect ILIM to LDO5 for a default 50mV current-limit threshold. In adjustable mode, the current-limit threshold is precisely 1/10 the voltage seen at ILIM. For an adjustable threshold, connect a resistive divider from REF to analog ground (GND) with ILIM connected to the center tap. The external 0.5V to 2V adjustment range corresponds to a 50mV to 200mV current-limit threshold. When adjusting the current limit, use 1% tolerance resistors and a divider current of approximately 10mA to prevent significant inaccuracy in the currentlimit tolerance. The current-sense method (Figure 7) and magnitude determines the achievable current-limit accuracy and power loss. Typically, higher current-sense limits provide 28 RDCR = L ⎡1 1⎤ + ⎢ CEQ ⎣ R1 R2 ⎥⎦ where RCS is the required current-sense resistance, and RDCR is the inductor’s series DC resistance. Use the worst-case inductance and RDCR values provided by the inductor manufacturer, adding some margin for the inductance drop over temperature and load. Output Capacitor Selection The output filter capacitor must have low enough equivalent series resistance (ESR) to meet output ripple and load-transient requirements, yet have high enough ESR to satisfy stability requirements. The output capacitance must be high enough to absorb the inductor energy while transitioning from full-load to no-load conditions without tripping the overvoltage fault protection. When using high capacitance, low-ESR capacitors ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers In Idle Mode, the inductor current becomes discontinuous, with peak currents set by the Idle Mode currentsense threshold (VIDLE = 0.2VLIMIT). In Idle Mode, the no-load output ripple may be determined as follows: V R VRIPPLE(P–P) = IDLE ESR RSENSE The actual capacitance value required relates to the physical size needed to achieve low ESR, as well as to the chemistry of the capacitor technology. Thus, the capacitor is usually selected by ESR and voltage rating rather than by capacitance value (this is true of tantalums, OS-CONs, polymers, and other electrolytics). When using low-capacity filter capacitors, such as ceramic capacitors, size is usually determined by the capacity needed to prevent V SAG and V SOAR from causing problems during load transients. Generally, once enough capacitance is added to meet the overshoot requirement, undershoot at the rising load edge is no longer a problem (see the VSAG and VSOAR equations in the Transient Response section). However, lowcapacity filter capacitors typically have high ESR zeros that may affect the overall stability (see the OutputCapacitor Stability Considerations section). Output-Capacitor Stability Considerations Stability is determined by the value of the ESR zero relative to the switching frequency. The boundary of instability is given by the following equation: f fESR ≤ OSC π where: fESR = 1 2πRESR COUT For a typical 300kHz application, the ESR zero frequency must be well below 95kHz, preferably below 50kHz. Tantalum and OS-CON capacitors in widespread use at the time of publication have typical ESR zero frequencies of 25kHz. In the design example used for inductor selection, the ESR needed to support 25mVP-P ripple is 25mV/1.5A = 16.7mΩ. One 220µF/4V Sanyo polymer (TPE) capacitor provides 15mΩ (max) ESR. This results in a zero at 48kHz, well within the bounds of stability. For low-input voltage applications where the duty cycle exceeds 50% (VOUT/VIN ≥ 50%), the output ripple voltage should not be greater than twice the internal slopecompensation voltage: VRIPPLE ≤ 0.02 x VOUT where VRIPPLE equals ΔIINDUCTOR x RESR. The worstcase ESR limit occurs when VIN = 2 x VOUT, so the above equation may be simplified to provide the following boundary condition: RESR ≤ 0.04 x L x fSW Do not put high-value ceramic capacitors directly across the feedback sense point without taking precautions to ensure stability. Large ceramic capacitors can have a high ESR zero frequency and cause erratic, unstable operation. However, it is easy to add enough series resistance by placing the capacitors a couple of inches downstream from the feedback sense point, which should be as close as possible to the inductor. Unstable operation manifests itself in two related but distinctly different ways: short/long pulses and cycle skipping resulting in lower frequency operation. Instability occurs due to noise on the output or because the ESR is so low that there is not enough voltage ramp in the output voltage signal. This “fools” the error comparator into triggering too early or into skipping a cycle. Cycle skipping is more annoying than harmful, resulting in nothing worse than increased output ripple. However, it can indicate the possible presence of loop instability due to insufficient ESR. Loop instability can result in oscillations at the output after line or load steps. Such perturbations are usually damped, but can cause the output voltage to rise above or fall below the tolerance limits. The easiest method for checking stability is to apply a very fast zero-to-max load transient and carefully observe the output-voltage-ripple envelope for overshoot and ringing. It may help to simultaneously monitor the inductor current with an AC current probe. Do not allow more than three cycles of ringing after the initial step-response under/overshoot. Input Capacitor Selection The input capacitor must meet the ripple current requirement (IRMS) imposed by the switching currents. For an out-of-phase regulator, the total RMS current in the input capacitor is a function of the load currents, ______________________________________________________________________________________ 29 MAX8744/MAX8745 (see stability requirements), the filter capacitor’s ESR dominates the output voltage ripple. So the output capacitor’s size depends on the maximum ESR required to meet the output voltage ripple (VRIPPLE(P-P)) specifications: VRIPPLE(P-P) = RESRILOAD(MAX)LIR MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers INPUT CAPACITOR RMS CURRENT vs. INPUT VOLTAGE 5.0 4.5 4.0 IN PHASE IRMS (A) 3.5 3.0 50/50 INTERLEAVING 2.5 2.0 1.5 40/60 OPTIMAL INTERLEAVING 1.0 0.5 0 0 8 10 12 14 16 18 20 VIN (V) INPUT RMS CURRENT FOR INTERLEAVED OPERATION: IRMS = ( OUT5 ( − IIN ) (DLX5 − DOL ) + (IOUT3 − IIN ) (DLX3 − DOL ) + IOUT5 + IOUT3 − IIN 2 2 V V DLX5 = OUT5 DLX3 = OUT3 VIN VIN VOUT5IOUT5 + VOUT3IOUT3 IIN = VIN ) 2 DOL + IIN2 (1 − DLX5 − DLX3 + DOL ) DOL = DUTY − CYCLE OVERLAP FRACTION INPUT RMS CURRENT FOR SINGLE-PHASE OPERATION: ( ⎛ V V − VOUT ⎜ OUT IN IRMS = ILOAD ⎜ VIN ⎜ ⎝ ) ⎞⎟ ⎟ ⎟ ⎠ Figure 8. Input RMS Current the input currents, the duty cycles, and the amount of overlap as defined in Figure 8. The 40/60 optimal interleaved architecture of the MAX8744/MAX8745 allows the input voltage to go as low 8.3V before the duty cycles begin to overlap. This offers improved efficiency over a regular 180° out-ofphase architecture where the duty cycles begin to overlap below 10V. Figure 8 shows the input-capacitor RMS current vs. input voltage for an application that requires 5V/5A and 3.3V/5A. This shows the improvement of the 40/60 optimal interleaving over 50/50 interleaving and in-phase operation. For most applications, nontantalum chemistries (ceramic, aluminum, or OS-CON) are preferred due to their resistance to power-up surge currents typical of systems with a mechanical switch or connector in series 30 with the input. Choose a capacitor that has less than 10°C temperature rise at the RMS input current for optimal reliability and lifetime. Power MOSFET Selection Most of the following MOSFET guidelines focus on the challenge of obtaining high load-current capability when using high-voltage (> 20V) AC adapters. Lowcurrent applications usually require less attention. The high-side MOSFET (NH) must be able to dissipate the resistive losses plus the switching losses at both VIN(MIN) and VIN(MAX). Ideally, the losses at VIN(MIN) should be roughly equal to the losses at VIN(MAX), with lower losses in between. If the losses at VIN(MIN) are significantly higher, consider increasing the size of NH. Conversely, if the losses at VIN(MAX) are significantly higher, consider reducing the size of NH. If VIN does not ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers Power MOSFET Dissipation Worst-case conduction losses occur at the duty-factor extremes. For the high-side MOSFET (NH), the worstcase power dissipation due to resistance occurs at minimum input voltage: ⎛V ⎞ 2 PD (NH Re sistive) = ⎜ OUT ⎟ (ILOAD ) RDS(ON) ⎝ VIN ⎠ Generally, use a small high-side MOSFET to reduce switching losses at high input voltages. However, the RDS(ON) required to stay within package power-dissipation limits often limits how small the MOSFET can be. The optimum occurs when the switching losses equal the conduction (RDS(ON)) losses. High-side switching losses do not become an issue until the input is greater than approximately 15V. Calculating the power dissipation in high-side MOSFETs (NH) due to switching losses is difficult, since it must allow for difficult-to-quantify factors that influence the turnon and turn-off times. These factors include the internal gate resistance, gate charge, threshold voltage, source inductance, and PC board layout characteristics. The following switching-loss calculation provides only a very rough estimate and is no substitute for breadboard evaluation, preferably including verification using a thermocouple mounted on NH: PD (NH Switching) = COSS VIN(MAX) ⎞ ⎛ ILOADQG(SW ) + ⎜ ⎟ VIN(MAX)fSW IGATE 2 ⎝ ⎠ where COSS is the output capacitance of NH, QG(SW) is the charge needed to turn on the NH MOSFET, and IGATE is the peak gate-drive source/sink current (1A typ). Switching losses in the high-side MOSFET can become a heat problem when maximum AC adapter voltages are applied, due to the squared term in the switchingloss equation (C x VIN2 x fSW). If the high-side MOSFET chosen for adequate RDS(ON) at low battery voltages becomes extraordinarily hot when subjected to V IN(MAX) , consider choosing another MOSFET with lower parasitic capacitance. For the low-side MOSFET (NL), the worst-case power dissipation always occurs at maximum battery voltage: PD (NL Re sistive) = ⎡ ⎛ VOUT ⎞ ⎤ 2 ⎢1 − ⎜ ⎟ ⎥(ILOAD ) RDS(ON) ⎢⎣ ⎝ VIN(MAX) ⎠ ⎥⎦ The absolute worst case for MOSFET power dissipation occurs under heavy overload conditions that are greater than ILOAD(MAX) but are not high enough to exceed the current limit and cause the fault latch to trip. To protect against this possibility, “overdesign” the circuit to tolerate: ⎛ ΔI ⎞ ILOAD = ILIMIT − ⎜ INDUCTOR ⎟ ⎝ ⎠ 2 where ILIMIT is the peak current allowed by the currentlimit circuit, including threshold tolerance and senseresistance variation. The MOSFETs must have a relatively large heatsink to handle the overload power dissipation. Choose a Schottky diode (DL) with a forward-voltage drop low enough to prevent the low-side MOSFET’s body diode from turning on during the dead time. As a general rule, select a diode with a DC current rating equal to a 1/3 the load current. This diode is optional and can be removed if efficiency is not critical. Boost Capacitors The boost capacitors (CBST) must be selected large enough to handle the gate-charging requirements of the high-side MOSFETs. Typically, 0.1µF ceramic capacitors work well for low-power applications driving medium-sized MOSFETs. However, high-current applications driving large, high-side MOSFETs require boost capacitors larger than 0.1µF. For these applications, select the boost capacitors to avoid discharging the capacitor more than 200mV while charging the highside MOSFETs’ gates: CBST = QGATE 200mV where QGATE is the total gate charge specified in the high-side MOSFET’s data sheet. For example, assume ______________________________________________________________________________________ 31 MAX8744/MAX8745 vary over a wide range, maximum efficiency is achieved by selecting a high-side MOSFET (NH) that has conduction losses equal to the switching losses. Choose a low-side MOSFET (NL) that has the lowest possible on-resistance (RDS(ON)), comes in a moderate-sized package (i.e., 8-pin SO, DPAK, or D2PAK), and is reasonably priced. Ensure that the MAX8744/MAX8745 DL_ gate driver can supply sufficient current to support the gate charge and the current injected into the parasitic drain-to-gate capacitor caused by the high-side MOSFET turning on; otherwise, cross-conduction problems may occur. Switching losses are not an issue for the low-side MOSFET since it is a zero-voltage switched device when used in the step-down topology. MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers the FDS6612A n-channel MOSFET is used on the high side. According to the manufacturer’s data sheet, a single FDS6612A has a maximum gate charge of 13nC (VGS = 5V). Using the above equation, the required boost capacitance would be: CBST = 13nC = 0.065μF 200mV Selecting the closest standard value, this example requires a 0.1µF ceramic capacitor. LDOA Design Procedure Output Voltage Selection Adjust the auxiliary linear regulator’s output voltage by connecting a resistive divider between OUTA and analog ground with the center tap connected to FBA (Figure 1). Select R6 in the 10kΩ to 30kΩ range, and calculate R5 with the following equation: ⎛V ⎞ R5 = R6⎜ OUTA − 1⎟ ⎝ VFBA ⎠ where VFBA = 1.0V. Transistor Selection The pass transistor must meet specifications for current gain (β), input capacitance, collector-emitter saturation voltage, and power dissipation. The transistor’s current gain limits the guaranteed maximum output current to: ⎛ ILOAD(MAX) = ⎜IDRV − VBE R BE ⎝ ⎞ ⎟ βMIN ⎠ where IDRV is the minimum guaranteed base drive current, VBE is the base-to-emitter voltage of the transistor, and RBE is the pullup resistor connected between the transistor’s base and emitter. Furthermore, the transistor’s current gain increases the linear regulator’s DC loop gain (see the LDOA Stability Requirements section), so excessive gain destabilizes the output. Therefore, transistors with current gain over 100 at the maximum output current can be difficult to stabilize and are not recommended. The transistor’s input capaci- 32 tance and input resistance also create a second pole, which could be low enough to make the output unstable when heavily loaded. The transistor’s saturation voltage at the maximum output current determines the minimum input-to-output voltage differential that the linear regulator supports. Alternatively, the package’s power dissipation could limit the useable maximum input-to-output voltage differential. The maximum power dissipation capability of the transistor’s package and mounting must exceed the actual power dissipation in the device. The power dissipation equals the maximum load current times the maximum input-to-output differential: PWR = ILOAD(MAX) (VINA -VOUTA) PWR = ILOAD(MAX) VCE LDOA Stability Requirements The MAX8744/MAX8745 linear-regulator controller uses an internal transconductance amplifier to drive an external pnp pass transistor. The transconductance amplifier, the pass transistor, the base-to-emitter resistor, and the output capacitor determine the loop stability. The transconductance amplifier regulates the output voltage by controlling the pass transistor’s base current. The total DC loop gain is approximately: ⎛ 5.5V ⎞ ⎛ IBIAShFE ⎞ A V(LDO) = ⎜ ⎟ ⎜1 + I ⎟ V ⎝ T ⎠⎝ LOAD ⎠ where VT is 26mV at room temperature, hFE is the pass transistor’s DC gain, and IBIAS is the current through the base-to-emitter resistor (RBE). The 680Ω base-toemitter resistor used in Figure 1 was chosen to provide a 1mA bias current (IBIAS). ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers 1) First, calculate the dominant pole set by the linear regulator’s output capacitor and the load resistor: fPOLE(LDO) = 1 2πCOUTARLOAD where COUTA is the output capacitance of the auxiliary LDO and RLOAD is the load resistance corresponding to the maximum load current. The unitygain crossover of the linear regulator is: fCROSSOVER = AV(LDO)fPOLE(LDO) 2) The pole caused by the internal amplifier delay is at approximately 1MHz: f POLE(AMP) ≈ 1MHz 3) Next, calculate the pole set by the transistor’s input capacitance, the transistor’s input resistance, and the base-to-emitter pullup resistor. Since the transistor’s input resistance (hFE/gm) is typically much greater than the base-to-emitter pullup resistance, the pole can be determined from the simplified equation: 1 fPOLE(CIN) ≈ 2πCINRIN g CIN = m 2πfT where gm is the transconductance of the pass transistor, and fT is the transition frequency. Both parameters can be found in the transistor’s data sheet. Therefore, the equation can be further reduced to: f f POLE(CIN) ≈ T hFE 4) Next, calculate the pole set by the linear regulator’s feedback resistance and the capacitance between FBA and ground (approximately 5pF including stray capacitance): f POLE(FBA) = 1 2πCFBA (R5 || R6) 5) Next, calculate the zero caused by the output capacitor’s ESR: fZERO(ESR) = 1 2πCOUTARESR where RESR is the equivalent series resistance of COUTA. 6) To ensure stability, choose COUTA large enough so that the crossover occurs well before the poles and zero calculated in steps 2 through 5. The poles in steps 3 and 4 generally occur at several MHz, and using ceramic output capacitors ensures the ESR zero occurs at several MHz as well. Placing the crossover frequency below 500kHz is typically sufficient to avoid the amplifier delay pole and generally works well, unless unusual component selection or extra capacitance moves the other poles or zero below 1MHz. A capacitor connected between the linear regulator’s output and the feedback node can improve the transient response and reduce the noise coupled into the feedback loop. If a low-dropout solution is required, an external pchannel MOSFET pass transistor could be used. However, a pMOS-based linear regulator requires higher output capacitance to stabilize the loop. The high gate capacitance of the p-channel MOSFET lowers the fPOLE(CIN) and can cause instability. A large output capacitance must be used to reduce the unity-gain bandwidth and ensure that the pole is well above the unity-gain crossover frequency. Applications Information Duty-Cycle Limits Minimum Input Voltage The minimum input operating voltage (dropout voltage) is restricted by the maximum duty-cycle specification (see the Electrical Characteristics table). For the best dropout performance, use the slowest switching frequency setting (200kHz, FSEL = GND). However, keep in mind that the transient performance gets worse as the step-down regulators approach the dropout voltage, so bulk output capacitance must be added (see the voltage sag and soar equations in the SMPS Design Procedure and Transient Response sections). The absolute point of dropout occurs when the inductor current ramps down during the off-time (ΔIDOWN) as much as it ramps up during the on-time (ΔIUP). This results in a minimum operating voltage defined by the following equation: ______________________________________________________________________________________ 33 MAX8744/MAX8745 The output capacitor and the load resistance create the dominant pole in the system. However, the internal amplifier delay, the pass transistor’s input capacitance, and the stray capacitance at the feedback node create additional poles in the system, and the output capacitor’s ESR generates a zero. For proper operation, use the following steps to ensure the linear-regulator stability: MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers ⎛ 1 ⎞ VIN(MIN) = VOUT + VCHG + h⎜ − 1⎟ (VOUT + VDIS ) ⎝ DMAX ⎠ where VCHG and VDIS are the parasitic voltage drops in the charge and discharge paths, respectively. A reasonable minimum value for h is 1.5, while the absolute minimum input voltage is calculated with h = 1. Maximum Input Voltage The MAX8744/MAX8745 controllers include a minimum on-time specification, which determines the maximum input operating voltage that maintains the selected switching frequency (see the Electrical Characteristics table). Operation above this maximum input voltage results in pulse-skipping operation, regardless of the operating mode selected by SKIP. At the beginning of each cycle, if the output voltage is still above the feedback threshold voltage, the controller does not trigger an on-time pulse, effectively skipping a cycle. This allows the controller to maintain regulation above the maximum input voltage, but forces the controller to effectively operate with a lower switching frequency. This results in an input threshold voltage at which the controller begins to skip pulses (VIN(SKIP)): ⎛ ⎞ 1 VIN(SKIP) = VOUT ⎜ ⎟ ⎝ fOSCt ON(MIN) ⎠ where fOSC is the switching frequency selected by FSEL. PC Board Layout Guidelines Careful PC board layout is critical to achieving low switching losses and clean, stable operation. The switching power stage requires particular attention (Figure 9). If possible, mount all the power components on the top side of the board, with their ground terminals flush against one another. Follow these guidelines for good PC board layout: Keep the high-current paths short, especially at the ground terminals. This practice is essential for stable, jitter-free operation. Keep the power traces and load connections short. This practice is essential for high efficiency. Using thick copper PC boards (2oz vs. 1oz) can enhance full-load efficiency by 1% or more. Correctly routing PC board 34 traces is a difficult task that must be approached in terms of fractions of centimeters, where a single milliohm of excess trace resistance causes a measurable efficiency penalty. Minimize current-sensing errors by connecting CSH_ and CSL_ directly across the current-sense resistor (RSENSE_). When trade-offs in trace lengths must be made, it is preferable to allow the inductor charging path to be made longer than the discharge path. For example, it is better to allow some extra distance between the input capacitors and the high-side MOSFET than to allow distance between the inductor and the low-side MOSFET or between the inductor and the output filter capacitor. Route high-speed switching nodes (BST_, LX_, DH_, and DL_) away from sensitive analog areas (REF, FB_, CSH_, CSL_). Layout Procedure Place the power components first, with ground terminals adjacent (N L _ source, C IN , C OUT _, and D L _ anode). If possible, make all these connections on the top layer with wide, copper-filled areas. Mount the controller IC adjacent to the low-side MOSFET, preferably on the back side opposite NL_ and NH_ in order to keep LX_, GND, DH_, and the DL_ gate-drive lines short and wide. The DL_ and DH_ gate traces must be short and wide (50 mils to 100 mils wide if the MOSFET is 1in from the controller IC) to keep the driver impedance low and for proper adaptive dead-time sensing. Group the gate-drive components (BST_ diode and capacitor, LDO5 bypass capacitor) together near the controller IC. Make the DC-DC controller ground connections as shown in Figures 1 and 9. This diagram can be viewed as having two separate ground planes: power ground, where all the high-power components go, and an analog ground plane for sensitive analog components. The analog ground plane and power ground plane must meet only at a single point directly at the IC. Connect the output power planes directly to the output filter capacitor positive and negative terminals with multiple vias. Place the entire DC-DC converter circuit as close to the load as is practical. ______________________________________________________________________________________ High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers MAX8744/MAX8745 MAX8744/MAX8745 CONNECT THE EXPOSED PAD TO ANALOG GND VIA TO POWER GROUND CONNECT GND AND PGND TO THE CONTROLLER AT ONE POINT ONLY AS SHOWN REF BYPASS CAPACITOR DUAL n-CHANNEL MOSFET KELVIN SENSE VIAS UNDER THE SENSE RESISTOR (REFER TO THE EVALUATION KIT) SINGLE n-CHANNEL MOSFETS INDUCTOR INDUCTOR DH LX DL CIN COUT CIN INPUT COUT INPUT COUT GROUND OUTPUT HIGH-POWER LAYOUT OUTPUT GROUND LOW-POWER LAYOUT Figure 9. PC Board Layout Chip Information TRANSISTOR COUNT: 6897 PROCESS: BiCMOS ______________________________________________________________________________________ 35 Package Information (The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information go to www.maxim-ic.com/packages.) QFN THIN.EPS MAX8744/MAX8745 High-Efficiency, Quad Output, Main PowerSupply Controllers for Notebook Computers PACKAGE OUTLINE, 16, 20, 28, 32, 40L THIN QFN, 5x5x0.8mm 21-0140 K 1 2 PACKAGE OUTLINE, 16, 20, 28, 32, 40L THIN QFN, 5x5x0.8mm 21-0140 K 2 2 Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. 36 Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 © 2006 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc.