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| 19-3626; Rev 0; 3/05 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers General Description The MAX8764 pulse-width modulation (PWM) controller provides high efficiency, excellent transient response, and high-DC output accuracy needed for stepping down high-voltage batteries to generate low-voltage CPU core or chipset/RAM supplies in notebook computers. Maxim's proprietary Quick-PWMTM quick-response, constant-on-time PWM control scheme handles wide input/output voltage ratios with ease and provides 100ns "instant-on" response to load transients while maintaining a relatively constant switching frequency. Efficiency is enhanced by an ability to drive very large synchronous-rectifier MOSFETs. Accurate current sensing to ensure reliable overload protection is available using an external current-sense resistor in series with the synchronous rectifier. Alternatively, the synchronous rectifier itself can be used for less-accurate current sensing at the lowest possible power dissipation. A high-output impedance in shutdown eliminates negative output voltages, saving the cost of a Schottky diode on the output. Single-stage buck conversion allows the MAX8764 to directly step down high-voltage batteries for the highest possible efficiency. Alternatively, two-stage conversion (stepping down the 5V system supply instead of the battery) at a higher switching frequency allows the minimum possible physical size. The MAX8764 is intended for CPU core, chipset, DRAM, or other low-voltage supplies as low as 1V. It is available in 20-pin QSOP and thin QFN packages and includes both adjustable overvoltage and undervoltage protection. For a dual step-down PWM controller with accurate current limit, refer to the MAX8743 data sheet. The MAX1714/MAX1715 single/dual PWM controllers are similar to the MAX8764, but do not use current-sense resistors. Ultrahigh Efficiency Accurate Current-Limit Option Quick-PWM with 100ns Load-Step Response 1% VOUT Accuracy Over Line and Load 1.8V/2.5V Fixed or 1V to 5.5V Adjustable Output Range 2V to 28V Battery Input Range 200/300/450/600kHz Switching Frequency Adjustable Overvoltage Protection Adjustable Undervoltage Protection 1.7ms Digital Soft-Start Drives Large Synchronous-Rectifier FETs 2V 1% Reference Output Power-Good Window Comparator Features MAX8764 Ordering Information PART MAX8764EEP MAX8764EEP+ MAX8764ETP MAX8764ETP+ TEMP RANGE -40C to +85C -40C to +85C -40C to +85C -40C to +85C PIN-PACKAGE 20 QSOP 20 QSOP 20 Thin QFN 20 Thin QFN +Denotes lead-free package. Minimal Operating Circuit BATTERY 4.5V TO 28V 5V INPUT VCC SHDN UVP ILIM BST DH MAX8764 LX REF DL PGOOD LATCH OVP FB OUT SKIP GND CS OUTPUT 2.5V VDD V+ Applications Notebook Computers CPU Core Supplies Chipset/RAM Supplies as Low as 1V 1.8V and 2.5V Supplies Quick-PWM is a trademark of Maxim Integrated Products, Inc. Pin Configurations appear at end of data sheet. ________________________________________________________________ Maxim Integrated Products 1 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. High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 ABSOLUTE MAXIMUM RATINGS V+ to GND ..............................................................-0.3V to +28V VCC, VDD to GND .....................................................-0.3V to +6V OUT, PGOOD, SHDN to GND ..................................-0.3V to +6V FB, ILIM, LATCH, OVP, REF, SKIP, TON, UVP to GND ..................................-0.3V to (VCC + 0.3V) BST to GND ............................................................-0.3V to +34V CS to GND.................................................................-6V to +30V DL to GND ..................................................-0.3V to (VDD + 0.3V) DH to LX .....................................................-0.3V to (BST + 0.3V) LX to BST..................................................................-6V to +0.3V REF Short Circuit to GND ...........................................Continuous Continuous Power Dissipation (TA = +70C) 20-Pin QSOP (derate 9.1mW/C above +70C)...........727mW 20-Pin 5mm x 5mm Thin QFN (derate 20.0mW/C above +70C).................................................................1.60W Operating Temperature Range ...........................-40C to +85C Junction Temperature ......................................................+150C Storage Temperature Range .............................-65C to +150C Lead Temperature (soldering, 10s) .................................+300C 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, V+ = 15V, VCC = VDD = 5V, SKIP = LATCH = GND, TA = 0C to +85C, unless otherwise noted. Typical values are at TA = +25C.) PARAMETER Input Voltage Range Error Comparator Threshold (DC Output Voltage Accuracy) (Note 1) Load Regulation Error Line Regulation Error FB Input Bias Current Output Adjustment Range OUT Input Resistance Soft-Start Ramp Time FB = GND FB = VCC or adjustable feedback mode Rising edge of SHDN to full current limit TON = GND (600kHz) On-Time V+ = 24V, VOUT = 2V (Note 2) (Note 2) FB forced above the regulation point FB forced above the regulation point SHDN = GND SHDN = GND SHDN = GND, V+ = 28V, VCC = VDD = 0 or 5V VCC = 4.5V to 5.5V, no external REF load IREF = 0 to 50A 1.98 TON = REF (450kHz) TON = unconnected (300kHz) TON = VCC (200kHz) Minimum Off-Time Quiescent Supply Current (VCC) Quiescent Supply Current (VDD) Quiescent Supply Current (V+) Shutdown Supply Current (VCC) Shutdown Supply Current (VDD) Shutdown Supply Current (V+) Reference Voltage Reference Load Regulation 140 175 260 380 Battery voltage, V+ VCC , VDD FB = OUT V+ = 4.5V to 28V, SKIP = VCC FB = GND FB = VCC CONDITIONS MIN 2 4.5 0.99 2.475 1.782 2.5 1.8 9 5 -0.1 1.0 90 70 190 145 1.7 160 200 290 425 400 550 <1 25 <1 <1 <1 2.00 180 225 320 470 500 800 5 40 5 5 5 2.02 0.01 ns A A A A A A V V ns +0.1 5.5 350 270 TYP MAX 28 5.5 1.01 2.525 1.818 mV mV A V k ms V UNITS V ILOAD = 0 to 3A, SKIP = VCC VCC = 4.5V to 5.5V, V+ = 4.5V to 28V 2 _______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, SKIP = LATCH = GND, TA = 0C to +85C, unless otherwise noted. Typical values are at TA = +25C.) PARAMETER REF Sink Current REF Fault Lockout Voltage Overvoltage Trip Threshold (Fixed-Threshold Mode) REF in regulation Falling edge, hysteresis = 40mV With respect to error comparator threshold, no load OVP = GND, rising edge, hysteresis = 1% External feedback, measured at FB with respect to VOVP, 1V < VOVP < 1.8V, rising edge, hysteresis =1% Overvoltage Comparator Offset (Adjustable-Threshold Mode) Internal feedback, measured at OUT with respect to the nominal OUT regulation voltage, 1V < VOVP < 1.8V, rising edge, hysteresis = 1% 1V < VOVP < 1.8V FB forced 2% above trip threshold 12 -30 CONDITIONS MIN 10 1.6 14.5 17 +30 TYP MAX UNITS A V % mV MAX8764 -3.5 -100 0 1.5 +3.5 +100 % nA s OVP Input Leakage Current Overvoltage Fault Propagation Delay Output Undervoltage Protection Trip Threshold (Fixed-Threshold Mode) Output Undervoltage Protection Trip Threshold (AdjustableThreshold Mode) UVP Input Leakage Current Output Undervoltage Protection Blanking Time PGOOD Trip Threshold (Lower) PGOOD Trip Threshold (Upper) PGOOD Propagation Delay PGOOD Output Low Voltage PGOOD Leakage Current ILIM Adjustment Range Current-Limit Threshold (Fixed) Current-Limit Threshold (Adjustable) Current-Limit Threshold (Negative Direction) Current-Limit Threshold (Zero Crossing) Thermal Shutdown Threshold VCC Undervoltage Lockout Threshold With respect to error comparator threshold, UVP = VCC External feedback, measured at FB with respect to VUVP, 0.4V < VUVP < 1V Internal feedback, measured at OUT with respect to the nominal OUT regulation voltage, 0.4V < VUVP < 1V 0.4V < VUVP < 1V From rising edge of SHDN With respect to error comparator threshold, no load With respect to error comparator threshold, no load FB forced 2% beyond PGOOD trip threshold, falling ISINK = 1mA High state, forced to 5.5V 65 70 75 % -40 -5 -100 10 -12.5 8.0 -10 10 10 <1 +40 +5 +100 30 -8.0 12.5 0.4 1 mV % nA ms % % s V A V mV mV mV mV C 0.25 GND - VCS, ILIM = VCC GND - VCS VILIM = 0.5V VILIM = 2V 90 40 170 -140 100 50 200 -117 3 +150 4.1 3.00 110 60 230 -95 GND - VCS, SKIP = VCC, ILIM = VCC, TA = +25C GND - VCS, SKIP = GND Hysteresis = 10C Rising edge, hysteresis = 20mV, PWM disabled below this level 4.4 V _______________________________________________________________________________________ 3 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, SKIP = LATCH = GND, TA = 0C to +85C, unless otherwise noted. Typical values are at TA = +25C.) PARAMETER DH Gate-Driver On-Resistance DL Gate-Driver On-Resistance DL Gate-Driver On-Resistance DH Gate-Driver Source/Sink Current DL Gate-Driver Source Current DL Gate-Driver Sink Current Dead Time Logic Input High Voltage Logic Input Low Voltage Logic Input Current Dual ModeTM Threshold, Low Dual Mode Threshold, High TON VCC Level TON Float Voltage TON Reference Level TON GND Level TON Input Current ILIM Input Leakage Current Forced to GND or VCC -3 -100 0 CONDITIONS BST - LX forced to 5V (Note 4) DL, high state (Note 4) DL, low state (Note 4) MAX8764EEP MAX8764ETP MAX8764EEP MAX8764ETP MAX8764EEP MAX8764ETP MIN TYP 1.5 1.5 1.5 1.5 0.5 0.5 1 1 3 35 26 2.4 0.8 -1 0.15 VCC - 1.5 1.9 VCC - 0.4 3.15 1.65 3.85 2.35 0.5 +3 +100 2.0 0.20 +1 0.25 VCC - 0.4 2.1 MAX 5 6 5 6 1.7 2.7 UNITS A A A ns V V A V V V V V V A nA DH forced to 2.5V, BST-LX forced to 5V DL forced to 2.5V DL forced to 5V DL rising DH rising LATCH, SHDN, SKIP LATCH, SHDN, SKIP LATCH, SHDN, SKIP OVP, UVP, FB OVP, UVP FB ELECTRICAL CHARACTERISTICS (Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, SKIP = LATCH = GND, TA = -40C to +85C, unless otherwise noted.) (Note 3) PARAMETER Input Voltage Range Error Comparator Threshold (DC Output Voltage Accuracy) Battery voltage, V+ VCC , VDD V+ = 4.5V to 28V, SKIP = VCC (Note 1) V+ = 24V, VOUT = 2V (Note 2) FB = OUT FB = GND FB = VCC TON = GND (600kHz) On-Time TON = REF (450kHz) TON = Unconnected (300kHz) TON = VCC (200kHz) CONDITIONS MIN 2 4.5 0.985 2.462 1.773 140 175 260 380 TYP MAX 28 5.5 1.015 2.538 1.827 180 225 320 470 ns V UNITS V Dual Mode is a trademark of Maxim Integrated Products, Inc. 4 _______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1, V+ = 15V, VCC = VDD = 5V, SKIP = LATCH = GND, TA = -40C to +85C, unless otherwise noted.) (Note 3) PARAMETER Minimum Off-Time Quiescent Supply Current (VCC) Quiescent Supply Current (VDD) Quiescent Supply Current (V+) Shutdown Supply Current (VCC) Shutdown Supply Current (VDD) Shutdown Supply Current (V+) Reference Voltage Overvoltage Trip Threshold (Fixed-Threshold Mode) (Note 2) FB forced above the regulation point FB forced above the regulation point Measured at V+ SHDN = GND SHDN = GND SHDN = GND, V+ = 28V, VCC = VDD = 0 or 5V VCC = 4.5V to 5.5V, no external REF load With respect to error comparator threshold, no load OVP = GND, rising edge, hysteresis = 1% External feedback, measured at FB with respect to VOVP, 1V < VOVP 1.8V, rising edge, hysteresis = 1% Internal feedback, measured at OUT with respect to the nominal OUT regulation voltage, 1V < VOVP < 1.8V With respect to error comparator threshold, UVP = VCC Measured at FB/OUT with respect to VUVP; 0.4V < VUVP < 1.0V With respect to error comparator threshold, no load OUT falling edge, hysteresis = 1% With respect to error comparator threshold, no load OUT rising edge, hysteresis = 1% ISINK = 1mA High state, forced to 5.5V GND - VCS, ILIM = VCC GND - VCS, VILIM = 0.5V GND - VCS, VILIM = 2V Rising edge, hysteresis = 20mV, PWM disabled below this level LATCH, SHDN, SKIP LATCH, SHDN, SKIP LATCH, SHDN, SKIP -1 85 35 160 4.1 2.4 0.8 +1 1.98 12 -30 -3.5 CONDITIONS MIN TYP MAX 500 800 5 40 5 5 5 2.02 17 +30 +3.5 UNITS ns A A A A A A V % mV % MAX8764 Overvoltage Comparator Offset (Adjustable-Threshold Mode) Output Undervoltage Protection Trip Threshold (Fixed Threshold Mode) Output Undervoltage Protection Trip Threshold (Adjustable Mode) PGOOD Trip Threshold (Lower) PGOOD Trip Threshold (Upper) PGOOD Output Low Voltage PGOOD Leakage Current Current-Limit Threshold (Fixed) Current-Limit Threshold (Adjustable) VCC Undervoltage Lockout Threshold Logic Input High Voltage Logic Input Low Voltage Logic Input Current 65 70 75 % -5 +5 % -12.5 7.5 -7.5 12.5 0.4 1 115 65 240 4.4 % % V A mV mV V V V A Note 1: When the inductor is in continuous conduction, the output voltage has a DC regulation level higher 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 1.5% due to slope compensation. Note 2: 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 3: Specifications to -40C are guaranteed by design, not production tested. Note 4: Production testing limitations due to package handling require relaxed maximum on-resistance specifications for the thin QFN package. The MAX8764EEP and MAX8764ETP contain the same die and the thin QFN package imposes no additional resistance in-circuit. _______________________________________________________________________________________ 5 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 __________________________________________Typical Operating Characteristics (Circuit of Figure 1, VIN = 15V, SKIP = LATCH = GND, TON = unconnected, TA = +25C, unless otherwise noted.) EFFICIENCY vs. LOAD CURRENT MAX8764 toc01 FREQUENCY vs. LOAD CURRENT MAX8764 toc02 FREQUENCY vs. INPUT VOLTAGE MAX8764 toc03 100 95 90 350 VIN = 7V, SKIP = VCC 300 250 200 150 100 50 0 VIN = 15V, SKIP = GND 0.01 0.1 1 VIN = 7V, SKIP = GND VIN = 15V, SKIP = VCC 320 310 FREQUENCY (kHz) 85 80 75 70 65 60 0.01 0.1 1 VIN = 20V VIN = 7V VIN = 12V FREQUENCY (kHz) EFFICIENCY (%) 300 290 ILOAD = 1A 280 10 0 5 10 15 20 25 30 INPUT VOLTAGE (V) 10 LOAD CURRENT (A) LOAD CURRENT (A) FREQUENCY vs. TEMPERATURE MAX8764 toc04 CONTINUOUS-TO-DISCONTINUOUS INDUCTOR CURRENT vs. INPUT VOLTAGE CONTINUOUS INDUCTOR CURRENT 700 LOAD CURRENT (mA) 600 500 400 300 200 100 DISCONTINUOUS INDUCTOR CURRENT MAX8764 toc05 CURRENT LIMIT vs. INPUT VOLTAGE 7 6 CURRENT LIMIT (A) 5 4 3 2 1 0 0 5 10 15 20 25 30 MAX8764 toc06 330 ILOAD = 4A 320 FREQUENCY (kHz) 800 8 310 ILOAD = 1A 300 290 -40 -25 -10 5 20 35 50 65 80 TEMPERATURE (C) 0 0 5 10 15 20 25 30 INPUT VOLTAGE (V) INPUT VOLTAGE (V) CURRENT LIMIT vs. TEMPERATURE MAX8764 toc07 NORMALIZED OVERVOLTAGE TRIP THRESHOLD vs. VOVP OVERVOLTAGE TRIP THRESHOLD (%) OVERVOLTAGE TRIP THRESHOLD OUTPUT VOLTAGE SET POINT 1.6 MAX8764 toc08 OVERVOLTAGE TRIP THRESHOLD vs. TEMPERATURE MAX8764 toc09 6 1.8 NORMALIZED THRESHOLD (V/V) 120 118 CURRENT LIMIT (A) 5 116 1.4 114 4 1.2 112 3 -40 -25 -10 5 20 35 50 65 80 TEMPERATURE (C) 1.0 1.0 1.2 1.4 VOVP (V) 1.6 1.8 110 -40 -15 10 35 60 85 TEMPERATURE (C) 6 _______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 Typical Operating Characteristics (continued) (Circuit of Figure 1, VIN = 15V, SKIP = LATCH = GND, TON = unconnected, TA = +25C, unless otherwise noted.) NO-LOAD SUPPLY CURRENT vs. INPUT VOLTAGE (PWM MODE) IIN 8 SUPPLY CURRENT (mA) MAX8764 toc10 NO-LOAD SUPPLY CURRENT vs. INPUT VOLTAGE (SKIP MODE) MAX8764 toc11 LOAD-TRANSIENT RESPONSE (PWM MODE) MAX8764 toc12A 10 0.8 SUPPLY CURRENT (mA) 0.6 ICC 0.4 VOUT AC-COUPLED 100mV/div 6 IDD 4 INDUCTOR CURRENT 2A/div 2 ICC 0 0 5 10 15 20 25 30 INPUT VOLTAGE (V) 0.2 IIN 0 0 5 10 15 20 25 30 INPUT VOLTAGE (V) IDD 20s/div DL 5V/div LOAD-TRANSIENT RESPONSE (SKIP MODE) MAX8764 toc12B OUTPUT OVERLOAD WAVEFORM (UVP = GND) VOUT AC-COUPLED 100mV/div OUTPUT OVERLOAD WAVEFORM (UVP = VCC) LOAD FET 2V/div VOUT 2V/div INDUCTOR CURRENT 5A/div DL 5V/div PGOOD 5V/div MAX8764 toc13A MAX8764 toc13B LOAD FET 2V/div VOUT 2V/div INDUCTOR CURRENT 5A/div DL 5V/div PGOOD 5V/div 40s/div INDUCTOR CURRENT 2A/div DL 5V/div 20s/div 40s/div STARTUP MAX8764 toc14 SHUTDOWN WAVEFORM MAX8764 toc15A OUTPUT OVERVOLTAGE WAVEFORM (OVP = GND) SHDN 5V/div VOUT 2V/div INDUCTOR CURRENT 5A/div DL 5V/div MAX8764 toc15B SHDN 5V/div VOUT 2V/div INDUCTOR CURRENT 5A/div DL 5V/div RLOAD = 0.4 400s/div PGOOD 5V/div VOUT 1V/div DL 5V/div INDUCTOR CURRENT 5A/div PGOOD 5V/div 1ms/div RLOAD = 0.4 100s/div PGOOD 5V/div _______________________________________________________________________________________ 7 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 Pin Description PIN QSOP THIN QFN NAME FUNCTION 1 18 CS Current-Sense Input. Connect a low-value, current-sense resistor between CS and GND for accurate current sensing. For lower power dissipation (less accurate) current sensing, connect CS to LX to use the synchronous rectifier as the sense resistor. The PWM controller does not begin a cycle unless the current sensed at CS is less than the current-limit threshold programmed at ILIM. Overvoltage Protection Latch Control Input. The synchronous rectifier MOSFET is always forced to the ON state when an overvoltage fault is detected. If LATCH is low, the synchronous rectifier remains on until either OVP is brought high, or VCC is cycled below 1V. If LATCH is high, the fault protections (UVP and OVP) are disabled. Shutdown Control Input. Drive SHDN to GND to force the MAX1844 into shutdown. Drive or connect to VCC for normal operation. A rising edge on SHDN clears the overvoltage and undervoltage protection fault latches. Overvoltage Protection Control Input. An overvoltage fault occurs if the internal or external feedback voltage exceeds the voltage at OVP. Apply a voltage between 1V and 1.8V to set the overvoltage limit between 100% and 180% of nominal output voltage. Connect to GND to assert the default overvoltage limit at 114% of the nominal output voltage. Connect OVP or LATCH to VCC to disable overvoltage fault detection and clear the overvoltage protection fault latch. Feedback Input. Connect to VCC for a 1.8V fixed output or to GND for a 2.5V fixed output. For an adjustable output (1V to 5.5V), connect FB to a resistive divider from the output voltage. The FB regulation level is 1V. Output-Voltage Sense Connection. Connect directly to the junction of the external output filter capacitors. OUT senses the output voltage to determine the on-time for the high-side switching MOSFET. OUT also serves as the feedback input in fixed-output modes. Current-Limit Threshold Adjustment. The current-limit threshold at CS is 0.1 times the voltage at ILIM. Connect ILIM to a resistive divider (typically from REF) to set the current-limit threshold between 25mV and 300mV (with 0.25V to 3V at ILIM). Connect to VCC to assert the 100mV default current-limit threshold. 2V Reference Voltage Output. Bypass to GND with a 0.22F (min) bypass capacitor. Can supply 50A for external loads. Reference turns off in shutdown. Undervoltage Protection Control Input. An undervoltage fault occurs if the internal or external feedback voltage is less than the voltage at UVP. Apply a voltage between 0.4V and 1V to set the undervoltage limit between 40% and 100% of the nominal output voltage. Connect to VCC to assert the default undervoltage limit of 70% of the nominal output voltage. Connect UVP to GND or LATCH to VCC to disable undervoltage fault detection and clear the undervoltage protection latch. Power-Good, Open-Drain Output. PGOOD is low when the output voltage is more than 10% above or below the normal regulation point or during soft-start. PGOOD is high impedance when the output is in regulation and the soft-start circuit has terminated. PGOOD is low in shutdown. Analog and Power Ground Synchronous Rectifier Gate-Driver Output. Swings from GND to VDD. Supply Input for the DL Gate Drive. Connect to the system supply voltage, 4.5V to 5.5V. Bypass to GND with a 1F (min) ceramic capacitor. 2 19 LATCH 3 20 SHDN 4 1 OVP 5 2 FB 6 3 OUT 7 4 ILIM 8 5 REF 9 6 UVP 10 11 12 13 7 8 9 10 PGOOD GND DL VDD 8 _______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers Pin Description (continued) PIN QSOP 14 THIN QFN 11 NAME FUNCTION Analog Supply Input. Connect to the system supply voltage, 4.5V to 5.5V, with a series 20 resistor. Bypass to GND with a 1F (min) ceramic capacitor. On-Time Selection-Control Input. This four-level logic input sets the nominal DH on-time. Connect to GND, REF, VCC, or leave TON unconnected to select the following nominal switching frequencies: GND = 600kHz, REF = 450kHz, floating = 300kHz, and VCC = 200kHz. Battery-Voltage Sense Connection. Connect to input power source. V+ is used only to set the PWM one-shot timing. Pulse-Skipping Control Input. Connect to VCC for low-noise, forced-PWM mode. Connect to GND to enable pulse-skipping operation. Boost Flying-Capacitor Connection. Connect to an external capacitor and diode according to the Standard Application Circuit (Figure 1). See the MOSFET Gate Drivers (DH, DL) section. External Inductor Connection. Connect LX to the switched side of the inductor. LX serves as the lower supply rail for the DH high-side gate driver. High-Side Gate-Driver Output. Swings from LX to BST. MAX8764 VCC 15 12 TON 16 17 18 19 20 13 14 15 16 17 V+ SKIP BST LX DH Table 1. Component Selection for Standard Applications COMPONENT C1 Input Capacitor 2.5V AT 4A 10F, 25V Taiyo Yuden TMK432BJ106KM or TDK C4532X5R1E106M 330F, 6V Kemet T510X477108M006AS or Sanyo 6TPB330M Nihon EP10QY03 4.7H Coilcraft DO33116P-682 or Sumida CDRH124-4R7MC Fairchild Semiconductor 1/2 FDS6982A Fairchild Semiconductor 1/2 FDS6982A 0.015 1%, 0.5W resistor IRC LR2010-01-R015F or Dale WSL-2010-R015F Table 2. Component Suppliers SUPPLIER Coilcraft Dale-Vishay Fairchild IRC Kemet NIEC (Nihon) Sanyo Sumida Taiyo Yuden TDK USA PHONE 847-639-6400 203-452-5664 408-822-2181 800-752-8708 408-986-0424 805-867-2555* 619-661-6835 847-956-0666 408-573-4150 847-390-4461 FACTORY FAX 1-847-639-1469 1-203-452-5670 1-408-721-1635 1-828-264-7204 1-408-986-1442 81-3-3494-7414 81-7-2070-1174 81-3-3607-5144 1-408-573-4159 1-847-390-4405 C2 Output Capacitor D1 Schottky L1 Inductor *Distributor Q1 High-Side MOSFET Q2 Low-Side MOSFET Standard Application Circuit The standard application circuit (Figure 1) generates a 2.5V rail for general-purpose use in a notebook computer. See Table 1 for component selections. Table 2 lists component manufacturers. RSENSE _______________________________________________________________________________________ 9 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 VIN 7V TO 20V 5V BIAS SUPPLY C5 4.7F R1 20 C6 3.3F C1 10F VCC UVP ON/OFF CONTROL LOW-NOISE CONTROL V+ SHDN SKIP MAX8764 VDD BST DH D2 CMPSH-3 Q1 C7 0.1F L1 4.7H VOUT 2.5V C2 330F LX DL CS Q2 D1 ILIM TON REF 270k C4 0.22F GND 130k OVP FB LATCH OUT RSENSE 15m 5V R2 100k PGOOD POWER-GOOD INDICATOR SEE TABLE 1 FOR OTHER COMPONENT SELECTIONS. Figure 1. Standard Application Circuit Detailed Description The MAX8764 buck controller is targeted for low-voltage power supplies for notebook computers. Maxim's proprietary Quick-PWM pulse-width modulator in the MAX8764 is specifically designed for handling fast load steps while maintaining a relatively constant operating frequency and inductor operating point over a wide range of input voltages. The Quick-PWM architecture circumvents the poor load-transient timing problems of fixed-frequency, current-mode PWMs while also avoiding the problems caused by widely varying switching frequencies in conventional constant-on-time and constant-off-time PWM schemes. 10 5V Bias Supply (VCC and VDD) The MAX8764 requires an external 5V bias supply in addition to the battery. Typically, this 5V bias supply is the notebook's 95% efficient 5V system supply. Keeping the bias supply external to the IC improves efficiency and eliminates the cost associated with the 5V linear regulator that would otherwise be needed to supply the PWM circuit and gate drivers. If stand-alone capability is needed, the 5V supply can be generated with an external linear regulator such as the MAX1615. The battery and 5V bias inputs can be connected together if the input source is a fixed 4.5V to 5.5V supply. If the 5V bias supply is powered up prior to the ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 IN 2V TO 28V V+ TOFF TON ON-TIME COMPUTE FROM OUT 1-SHOT TRIG Q MAX8764 BST DH LX 5V TON TRIG 1-SHOT SKIP SHDN OVP 1.14V REF ERROR AMP Q S R Q OUTPUT VDD DL S Q R +5V 0.1V VCC - 1V LATCH POR 20ms TIMER OVP/UVP LATCH R 9R ILIM 0.1V CURRENT LIMIT 1.0V VCC - 1V CS VCC - 1V 0.7V ZERO CROSSING GND OUT CHIP SUPPLY 5V VCC UVP REF -10% REF +10% x2 PGOOD FEEDBACK MUX (SEE FIGURE 6) 2V REF REF FB Figure 2. MAX8764 Functional Diagram battery supply, the enable signal (SHDN) must be delayed until the battery voltage is present to ensure startup. The 5V bias supply provides VCC and gate-drive power, so the maximum current drawn is: IBIAS = ICC + f (QG1 + QG2) = 5mA to 30mA (typ) where ICC is 550A (typ), f is the switching frequency, and QG1 and QG2 are the MOSFET data sheet total gate-charge specification limits at VGS = 5V. Free-Running, Constant-On-Time PWM Controller with Input Feed-Forward The Quick-PWM control architecture is a pseudo-fixed-frequency, constant-on-time, on-demand PWM with voltage feed-forward (Figure 2). This architecture relies on the output filter capacitor's ESR to act as a current-sense resistor, so the output ripple voltage provides the PWM ramp signal. The control algorithm is simple: the high-side switch on-time is determined solely by a one-shot whose pulse ______________________________________________________________________________________ 11 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 Table 3. Operating Mode Truth Table SHDN 0 SKIP X DL Low MODE Shutdown, output UVP fault, thermal shutdown, UVLO Run (PWM), low noise COMMENTS Low-power shutdown state. DL is forced to GND. ICC < 1A typ. Low-noise operation with no automatic switchover. Fixed-frequency PWM action is forced regardless of load. Inductor current reverses at light-load levels. Low noise. High IQ. Normal operation with automatic PWM/PFM switchover for pulse skipping at light loads. Best light-load efficiency. Fault latch has been set by overvoltage protection. Device remains in FAULT mode until VCC power is cycled. 1 VCC Switching 1 1 GND X Switching High Run (PFM/PWM) Fault Table 4. Frequency Selection Guidelines FREQUENCY (kHz) 200 TON = VCC TYPICAL APPLICATION 4-cell Li+ notebook COMMENTS Use for absolute best efficiency. easy design methodology and predictable output voltage ripple. The on-time is given by: On-Time = K (VOUT + 0.075V) / VIN where K (switching period) is set by the TON pin-strap connection (Table 4), and 0.075V is an approximation to accommodate for the expected drop across the low-side MOSFET switch. One-shot timing error increases for the shorter on-time settings due to fixed propagation delays; it is approximately 12.5% at 600kHz and 450kHz, and 10% at the two slower settings. This translates to reduced switching-frequency accuracy at higher frequencies (Table 5). Switching frequency increases as a function of load current due to the increasing drop across the low-side MOSFET, which causes a faster inductor-current discharge ramp. The on-times guaranteed in the Electrical Characteristics are influenced by switching delays in the external high-side power MOSFET. Two external factors that influence switching-frequency accuracy are resistive drops in the two conduction loops (including inductor and PC board resistance) and the dead-time effect. These effects are the largest contributors to the change of frequency with changing load current. The dead-time effect increases the effective on-time, reducing the switching frequency as one or both dead times are added to the effective on-time. It occurs only in PWM mode (SKIP = high) when the inductor current reverses at light or negative load currents. With reversed inductor current, the inductor's EMF causes LX to go high earlier than normal, extending the ontime by a period equal to the low-to-high dead time. For loads above the critical conduction point, the actual switching frequency is: VOUT + VDROP1 f= t ON (VIN + VDROP2 ) 300 Considered mainstream 4-cell Li+ notebook TON = Floating by current standards. 450 TON = REF 600 TON = GND Useful in 3-cell systems for lighter loads than the CPU core or where size is key. Good operating point for compound buck designs or desktop circuits. 3-cell Li+ notebook +5V input width is inversely proportional to input voltage and directly proportional to output voltage. Another one-shot sets a minimum off-time (400ns typ). The on-time, one-shot is triggered if the error comparator is low, the low-side switch current is below the current-limit threshold, and the minimum off-time, one-shot has timed out. On-Time One-Shot (TON) The heart of the PWM core is the one-shot that sets the high-side switch on-time. This fast, low-jitter, adjustable one-shot includes circuitry that varies the on-time in response to battery and output voltage. The high-side switch on-time is inversely proportional to the battery voltage as measured by the V+ input, and proportional to the output voltage. This algorithm results in a nearly constant switching frequency despite the lack of a fixedfrequency clock generator. The benefits of a constant switching frequency are twofold: first, the frequency can be selected to avoid noise-sensitive regions such as the 455kHz IF band; second, the inductor ripple-current operating point remains relatively constant, resulting in 12 ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 i VBATT -VOUT = L t INDUCTOR CURRENT IPEAK IPEAK INDUCTOR CURRENT ILOAD ILOAD = IPEAK / 2 ILIMIT 0 ON-TIME TIME 0 TIME Figure 3. Pulse-Skipping/Discontinuous Crossover Point Figure 4. ``Valley'' Current-Limit Threshold Point where VDROP1 is the sum of the parasitic voltage drops in the inductor discharge path, including synchronous rectifier, inductor, and PC board resistances; VDROP2 is the sum of the resistances in the charging path, and tON is the on-time calculated by the MAX8764. Automatic Pulse-Skipping Switchover In skip mode (SKIP low), an inherent automatic switchover to PFM takes place at light loads (Table 3). This switchover is affected by a comparator that truncates the low-side switch on-time at the inductor current's zero crossing. 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; see the Continuous-to-Discontinuous Inductor Current vs. Input Voltage graph in the Typical Operating Characteristics). In low-duty-cycle applications, this threshold is relatively constant, with only a minor dependence on battery voltage. I LOAD(SKIP) KVOUT V -V x IN OUT 2L VIN 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 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). DC output accuracy specifications refer to the threshold of the error comparator. When the inductor is in continuous conduction, the output voltage has a DC regulation level higher than the trip level by 50% of the ripple. In discontinuous conduction (SKIP = GND, light load), the output voltage has a DC regulation level higher than the error-comparator threshold by approximately 1.5% due to slope compensation. Forced-PWM Mode (SKIP = High) The low-noise, forced-PWM mode (SKIP = high) disables the zero-crossing comparator, which controls the lowside switch on-time. This causes the low-side gate-drive waveform to become the complement of the high-side gate-drive waveform. This in turn causes the inductor current to reverse 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, but it comes at a cost: the no-load battery current can be 10mA to 40mA, depending on the external MOSFETs. Forced-PWM mode is most useful for reducing audiofrequency noise, improving load-transient response, providing sink-current capability for dynamic output voltage adjustment, and improving the cross-regulation of multiple-output applications that use a flyback transformer or coupled inductor. where K is the on-time scale factor (Table 5). The loadcurrent level at which PFM/PWM crossover occurs, ILOAD(SKIP), is equal to 1/2 the peak-to-peak ripple current, which is a function of the inductor value (Figure 3). For example, in the Standard Application Circuit with K = 3.3s (Table 5), VOUT = 2.5V, VIN = 15V, and L = 6.8H, switchover to pulse-skipping operation occurs at ILOAD = 0.51A or about 1/8 full load. The crossover point occurs at an even lower value if a swinging (soft-saturation) inductor is used. The switching waveforms may appear noisy and asynchronous when light loading causes pulse-skipping operation, but this is a normal operating condition that ______________________________________________________________________________________ 13 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 Current-Limit Circuit (ILIM) The current-limit circuit employs a unique "valley" current-sensing algorithm (Figure 4). If the magnitude of the current-sense voltage at CS is above the current-limit threshold, the PWM is not allowed to initiate a new cycle. The actual peak current is greater than the current-limit threshold by an amount equal to the inductor ripple current. Therefore, the exact current-limit characteristic and maximum load capability are a function of the sense resistance, inductor value, and battery voltage. There is also a negative current limit that prevents 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 therefore tracks the positive current limit when ILIM is adjusted. The current-limit threshold is adjusted with an external resistor-divider at ILIM. A 1A (min) divider current is recommended. The current-limit threshold adjustment range is from 25mV to 300mV. In the adjustable mode, the current-limit threshold voltage is precisely 1/10 the voltage seen at ILIM. The threshold defaults to 100mV when ILIM is connected to VCC. The logic threshold for switchover to the 100mV default value is approximately VCC - 1V. Carefully observe the PC board layout guidelines to ensure that noise and DC errors do not corrupt the current-sense signal seen by CS. Mount or place the IC close to the low-side MOSFET and sense resistor with short, direct traces, making a Kelvin sense connection to the sense resistor. In Figure 1, the Schottky diode (D1) provides a current path parallel to the Q2/RSENSE current path. Accurate current sensing demands D1 to be off while Q2 conducts. Avoid large current-sense voltages that, combined with the voltages across Q2, would allow D1 to conduct. If very large sense voltages are used, connect D1 in parallel with Q2. 5 +5V VIN BST DH LX MAX8764 Figure 5. Reducing the Switching-Node Rise Time properly; otherwise, the sense circuitry in the MAX8764 interprets the MOSFET gate as "off" while there is actually still charge left on the gate. Use very short, wide traces measuring no more than 20 squares (50 mils to 100 mils wide if the MOSFET is 1in from the MAX8764). The dead time at the other edge (DH turning off) is determined by a fixed 35ns (typ) internal delay. The internal pulldown transistor that drives DL low is robust, with a 0.5 (typ) on-resistance. This helps prevent DL from being pulled up during the fast rise time of the inductor node, due to capacitive coupling from the drain to the gate of the low-side synchronous-rectifier MOSFET. However, for high-current applications, there are still some combinations of high- and low-side FETs that will cause excessive gate-drain coupling, which can lead to efficiency-killing, EMI-producing, shoot-through currents. This is often remedied by adding a resistor in series with BST, which increases the turn-on time of the high-side FET without degrading the turn-off time (Figure 5). POR, UVLO, and Soft-Start Power-on reset (POR) occurs when VCC rises above approximately 2V, resetting the fault latch and soft-start counter, and preparing the PWM for operation. Until VCC reaches 4.2V, VCC undervoltage lockout (UVLO) circuitry inhibits switching. DL is held low. When VCC rises above 4.2V, an internal digital soft-start timer begins to ramp up the maximum allowed current limit. The ramp occurs in five steps: 20%, 40%, 60%, 80%, and 100%; 100% current is available after 1.7ms 50%. 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 the notebook environment, where a large VBATT VOUT differential exists. An adaptive dead-time circuit monitors the DL output and prevents the high-side FET from turning on until DL is fully off. There must be a lowresistance, low-inductance path from the DL driver to the MOSFET gate for the adaptive dead-time circuit to work 14 ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers Power-Good Output (PGOOD) The PGOOD window comparator continuously monitors the output. PGOOD is actively held low in shutdown, standby, and soft-start. After digital soft-start terminates, PGOOD is released if the output is within 10% of the nominal output voltage setting. Note that the PGOOD window detector is completely independent of the overvoltage and undervoltage protection fault detectors. Fixed-Output Voltages The MAX8764's Dual Mode operation allows the selection of common voltages without requiring external components (Figure 6). Connect FB to GND for a fixed 2.5V output or to VCC for a 1.8V output, or connect FB directly to OUT for a fixed 1V output. MAX8764 Output Overvoltage Protection OVP controls the output overvoltage protection function. Connect OVP to VCC or LATCH to VCC to disable overvoltage protection. If overvoltage protection is enabled (OVP < 1.8V, LATCH = GND), the output is continuously monitored. If the output exceeds the overvoltage protection threshold, overvoltage protection is triggered and the DL low-side gate-driver output is forced high. This turns on the low-side MOSFET switch to rapidly discharge the output capacitor and reduce the output voltage. If LATCH is high, the overvoltage protection is disabled. If LATCH is low, the DL gate-driver output remains high until OVP is driven to V CC , or V CC is cycled below 1V. When the condition that caused the overvoltage persists (such as a shorted high-side MOSFET), the battery fuse opens. Note that forcing DL high causes the output voltage to go slightly negative when energy has been previously stored in the LC tank circuit (see the output overvoltage waveforms in the Typical Operating Characteristics). If the load cannot tolerate being forced to a negative voltage, it may be desirable to place a power Schottky diode across the output to act as a reverse-polarity clamp. Setting VOUT with a Resistor-Divider The output voltage can be adjusted from 1V to 5.5V with a resistor-divider if desired (Figure 7). The equation for adjusting the output voltage is: R1 VOUT = VFB 1 + R2 where VFB is 1V. Design Procedure Component selection for the MAX8764 is primarily dictated by the following four criteria: 1) 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. Lower input voltages result in better efficiency. OUT TO ERROR AMP FIXED 1.8V MAX8764 Output Undervoltage Protection UVP controls the output undervoltage protection function. Connect UVP to GND or LATCH to VCC to disable undervoltage protection. The output undervoltage protection function is similar to foldback current limiting but employs a timer and latch rather than a variable current limit. If the output voltage is below the undervoltage protection threshold after the output undervoltage protection blanking time has elapsed, the PWM is latched off, DL is pulled low, and the controller does not restart until VCC power is cycled. SHDN is toggled, or UVP is pulled below 0.4V. Connect UVP to VCC to enable the default undervoltage trip threshold of 70% of nominal. To select a different threshold, drive UVP to a voltage between 0.4V and 1V for a threshold between 40% and 100% of nominal. Figure 6. Feedback Mux ______________________________________________________________________________________ 15 FIXED 2.5V FB 0.2V 2V High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers 2) Maximum load current. There are two values to consider. The peak load current (ILOAD(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. 3) 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 (Table 4). 4) Inductor operating point. This choice provides trade-offs between size vs. efficiency. Low inductor values cause large ripple currents, resulting in the smallest size, but poor efficiency and high output ripple. 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 MAX8764's pulse-skipping algorithm initiates skip mode at the critical conduction point. So, the inductor operating point also determines the load-current value at which PFM/PWM switchover occurs. These four factors impact the component selection process. Selecting components and calculating their effect on the MAX8764's operation is best done with a spreadsheet. Using the formulas provided, calculate the LIR (the ratio of the inductor ripple current to the designed maximum load current) for both the minimum and maximum input voltages. Maintaining an LIR within a 20% to 50% range is recommended. The use of a spreadsheet allows quick evaluation of component selection. MAX8764 VBATT DH VOUT DL CS OUT FB R2 R1 MAX8764 GND Figure 7. Setting VOUT with a Resistor-Divider L= 1.5V (7V -1.5V) = 1.49H 7V x 300kHz x 0.33 x 8A Find a low-loss inductor having the lowest possible DC resistance that fits in the allotted dimensions. 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): IPEAK = ILOAD(MAX) + [(LIR / 2) ILOAD(MAX)] Most inductor manufacturers provide inductors in standard values, such as 1.0H, 1.5H, 2.2H, 3.3H, etc. Also look for nonstandard 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. Transient Response The inductor ripple current also impacts transientresponse performance, especially at low VIN - VOUT differentials. Low inductor values allow the inductor current to slew faster, replenishing charge removed from the output filter capacitors by a sudden load step. The amount of output sag is also a function of the maximum duty factor, which can be calculated from the ontime and minimum off-time: Inductor Selection The switching frequency and inductor operating point determine the inductor value as follows: L= VOUT (VIN - VOUT ) VIN x f x LIR x I LOAD(MAX) Example: ILOAD(MAX) = 8A, VIN = 7V, VOUT = 1.5V, f = 300kHz, 33% ripple current or LIR = 0.33: 16 ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 VSAG = where DUTY = K (VOUT + 0.075V)/ VIN K (VOUT + 0.075V)/ VOUT + min off - time MAX8764 DL (I LOAD(MAX) )2 x L 2 x COUT x DUTY (VIN(MIN) - VOUT ) a) b) LX MAX8764 LX DL and minimum off-time = 400ns (typ) (see Table 5 for K values). The amount of overshoot during a full-load to no-load transient due to stored inductor energy can be calculated as: L= VOUT f x LIR x ILOAD(MAX) CS CS Figure 8. Current-Sense Circuits Setting the Current Limit For most applications, set the MAX8764 current limit by the following procedure: 1) Determine the minimum (valley) inductor current IL(MIN) under conditions when VIN is small, VOUT is large, and load current is maximum. The minimum inductor current is ILOAD minus half the ripple current (Figure 4). 2) The sense resistor determines the achievable current-limit accuracy. There is a trade-off between current-limit accuracy and sense-resistor power dissipation. Most applications employ a current-sense voltage of 50mV to 100mV. Choose a sense resistor so that: RSENSE = CS Threshold Voltage / IL(MIN) Extremely cost-sensitive applications that do not require high-accuracy current sensing can use the onresistance of the low-side MOSFET switch in place of the sense resistor by connecting CS to LX (Figure 8b). Use the worst-case value for RDS(ON) from the MOSFET Q2 data sheet, and add a margin of 0.5%/C for the rise in R DS(ON) with temperature. Then use that RDS(ON) value and IL(MIN) from step 1 above to determine the CS threshold voltage. If the default 100mV threshold is unacceptable, set the value as in step 2 above. In all cases, ensure an acceptable CS threshold voltage despite inaccuracies in resistor values. transient requirements, yet have high enough ESR to satisfy stability requirements. For CPU core voltage converters and other applications where the output is subject to violent load transients, the output capacitor's size depends on how much ESR is needed to prevent the output from dipping too low under a load transient. Ignoring the sag due to finite capacitance: VDIP RESR I LOAD(MAX) In nonCPU applications, the output capacitor's size often depends on how much ESR is needed to maintain an acceptable level of output voltage ripple: VP-P RESR LIR x I LOAD(MAX) The actual microfarad 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, and other electrolytics). When using low-capacity filter capacitors, such as ceramic or polymer types, capacitor size is usually determined by the capacity needed to prevent VSAG and VSOAR 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 (also, see the VSAG and VSOAR equation in the Transient Response section). Output Capacitor Selection The output filter capacitor must have low enough effective series resistance (ESR) to meet output ripple and load- ______________________________________________________________________________________ 17 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 Output Capacitor Stability Considerations Stability is determined by the value of the ESR zero relative to the switching frequency. The point of instability is given by the following equation: f ESR = where: f ESR = f allow more than one cycle of ringing after the initial step-response under- or overshoot. Input Capacitor Selection The input capacitor must meet the ripple current requirement (IRMS) imposed by the switching currents. Nontantalum chemistries (ceramic, aluminum, or OSCON) are preferred due to their resistance to power-up surge currents: VOUT VIN - VOUT IRMS = ILOAD VIN 1 2 x x RESR x 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 60mV P-P ripple is 60mV/2.7A = 22m. Two 470F/4V Kemet T510 low-ESR tantalum capacitors in parallel provide 22m (max) ESR. Their typical combined ESR results in a zero at 27kHz, well within the bounds of stability. 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: double-pulsing and fast-feedback loop instability. Double-pulsing 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 a new cycle immediately after the 400ns minimum off-time period has expired. Double-pulsing is more annoying than harmful, resulting in nothing worse than increased output ripple. However, it can indicate the possible presence of loop instability, which is caused by insufficient ESR. Loop instability can result in oscillations at the output after line or load perturbations that can trip the overvoltage protection latch or cause the output voltage to fall below the tolerance limit. 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 can help to monitor simultaneously the inductor current with an AC current probe. Do not 18 For optimal circuit reliability, choose a capacitor that has less than 10C temperature rise at the peak ripple current. Power MOSFET Selection Most of the following MOSFET guidelines focus on the challenge of obtaining high load-current capability (>5A) when using high-voltage (>20V) AC adapters. Low-current applications usually require less attention. For maximum efficiency, choose a high-side MOSFET (Q1) that has conduction losses equal to the switching losses at the optimum battery voltage (15V). Check to ensure that the conduction losses at minimum input voltage do not exceed the package thermal limits or violate the overall thermal budget. Check to ensure that conduction losses plus switching losses at the maximum input voltage do not exceed the package ratings or violate the overall thermal budget. Choose a low-side MOSFET (Q2) that has the lowest possible RDS(ON), comes in a moderate to small package (i.e., 8-pin SO), and is reasonably priced. Ensure that the MAX8764 DL gate driver can drive Q2; in other words, check that the gate is not pulled up by the highside switch turn on, due to parasitic drain-to-gate capacitance, causing crossconduction problems. Switching losses are not an issue for the low-side MOSFET since it is a zero-voltage switched device when used in the buck topology. MOSFET Power Dissipation Worst-case conduction losses occur at the duty factor extremes. For the high-side MOSFET, the worst-case power dissipation due to resistance occurs at minimum battery voltage: PD(Q1 Resistive) = (VOUT / VIN(MIN)) ILOAD2 RDS(ON) Generally, a small high-side MOSFET is desired to reduce switching losses at high input voltages. However, the RDS(ON) required to stay within package power-dissi- ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers pation limits often limits how small the MOSFET can be. Again, the optimum occurs when the switching (AC) losses equal the conduction (RDS(ON)) losses. High-side switching losses do not usually become an issue until the input is greater than approximately 15V. Switching losses in the high-side MOSFET can become an insidious heat problem when maximum AC adapter voltages are applied, due to the squared term in the CV2f switching loss equation. If the high-side MOSFET chosen for adequate RDS(ON) at low battery voltages becomes extraordinarily hot when subjected to VIN(MAX), reconsider the choice of MOSFET. Calculating the power dissipation in Q1 due to switching losses is difficult, since it must allow for difficult-to-quantify factors that influence the turn-on 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 a sanity check using a thermocouple mounted on Q1: CRSS x VIN(MAX)2 x f x ILOAD IGATE where CRSS is the reverse transfer capacitance of Q1, and IGATE is the peak gate-drive source/sink current (1A typ). PD(Q1 switching) = For the low-side MOSFET, Q2, the worst-case power dissipation always occurs at maximum battery voltage: PD(Q2) = (1 - VOUT / VIN(MAX)) ILOAD2 RDS(ON) The absolute worst case for MOSFET power dissipation occurs under heavy overloads that are greater than ILOAD(MAX) but are not quite high enough to exceed the current limit. To protect against this possibility, you must "overdesign" the circuit to tolerate ILOAD = ILIMIT(HIGH) + [(LIR / 2) ILOAD(MAX)], where ILIMIT(HIGH) is the maximum valley current allowed by the current-limit circuit, including threshold tolerance and sense-resistance variation. If short-circuit protection without overload protection is adequate, enable undervoltage protection, and use ILOAD(MAX) to calculate component stresses. Choose a Schottky diode D1 having a forward voltage drop low enough to prevent the Q2 MOSFET body diode from turning on during the dead time. As a general rule, a diode having a DC current rating equal to 1/3 of the load current is sufficient. This diode is optional, and if efficiency is not critical it can be removed. Applications Information Dropout Performance The output voltage adjust range for continuous-conduction operation is restricted by the nonadjustable 500ns (max) minimum off-time one-shot. For best dropout performance, use the slower (200kHz) on-time settings. When working with low input voltages, the duty-factor limit must be calculated using worst-case values for onand off-times. Manufacturing tolerances and internal propagation delays introduce an error to the TON Kfactor. This error is greater at higher frequencies (Table 5). Also, keep in mind that transient response performance of buck regulators operated close to dropout is poor, and bulk output capacitance must often be added (see the V SAG equation in the Transient Response section). The absolute point of dropout is when the inductor current ramps down during the minimum off-time (IDOWN) as much as it ramps up during the on-time (IUP). The ratio h = IUP/IDOWN indicates the circuit's ability to slew the inductor current higher in response to increased load, and must always be greater than 1. As h approaches 1, the absolute minimum dropout point, the inductor current is less able to increase during each switching cycle, and V SAG greatly increases unless additional output capacitance is used. A reasonable minimum value for h is 1.5, but this can be adjusted up or down to allow trade-offs between V SAG , output capacitance, and minimum operating voltage. For a given value of h, the minimum operating voltage can be calculated as: VIN(MIN) = MAX8764 t OFF(MIN ) x h 1- K (VOUT + VDROP1) + VDROP2 - VDROP1 where VDROP1 and VDROP2 are the parasitic voltage drops in the discharge and charge paths, tOFF(MIN) is from the Electrical Characteristics table, and K is taken from Table 5. The absolute minimum input voltage is calculated with h = 1. If the calculated VIN(MIN) is greater than the required minimum input voltage, operating frequency must be reduced or output capacitance added to obtain an acceptable VSAG. If operation near dropout is anticipated, calculate VSAG to be sure of adequate transient response. ______________________________________________________________________________________ 19 High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 BOTTOM SIDE TOP SIDE VIN Q1 AGND PLANE VIA TO IC CS PIN VIA RS Q2 Q C1 REF BYPASS PGND PLANE VCC BYPASS VDD BYPASS VIA TO POWER GROUND L1 D1 VIA TO PGND PLANE AND IC GND PIN C2 USE AGND PLANE TO: - BYPASS VCC AND REF - TERMINATE EXTERNAL FB, ILIM, OVP, UVP DIVIDERS - PIN-STRAP CONTROL INPUTS USE PGND PLANE TO: - BYPASS VDD - CONNECT IC GND PIN TO TOP-SIDE POWER GROUND VOUT VIA TO IC OUT POWER GROUND Figure 9. Power-Stage PC Board Layout Example Table 5. Approximate K-Factor Errors TON K SETTING FACTOR (kHz) (s) 200 300 450 600 5 3.3 2.2 1.7 APPROXIMATE K-FACTOR ERROR (%) 10 10 12.5 12.5 MINIMUM VIN AT VOUT = 2V (V) 2.6 2.9 3.2 3.6 VDROP1 = VDROP2 = 100mV h = 1.5: VIN(MIN) = 0.5s x 1.5 1- 2.97s (2.5V + 0.1V) + 0.1V - 0.1V = 3.48V Calculating again with h = 1 gives the absolute limit of dropout: Dropout Design Example: VOUT = 2.5V fsw = 300kHz K = 1.8s, worst-case K = 2.97s tOFF(MIN) = 500ns 20 VIN(MIN) = 0.5s x 1 1- 2.97s (2.5V + 0.1V) - 0.1V + 0.1V = 3.13V ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers Therefore, VIN must be greater than 3.13V, even with very large output capacitance, and a practical input voltage with reasonable output capacitance would be 3.48V. 4) Make the DC-DC controller ground connections as shown in Figure 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. 5) 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. MAX8764 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 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 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 CS directly to the RSENSE terminal. * 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 lowside 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, CS). Pin Configurations TOP VIEW + CS 1 LATCH 2 SHDN 3 OVP 4 FB 5 OUT 6 ILIM 7 REF 8 UVP 9 PGOOD 10 20 DH 19 LX 18 BST 17 SKIP MAX8764EEP 16 V+ 15 TON 14 VCC 13 VDD 12 DL 11 GND QSOP SKIP TON 12 BST 15 LX 16 DH 17 CS 18 LATCH 19 SHDN 20 14 13 VCC 11 10 VDD 9 8 DL GND PGOOD UVP 7 6 5 REF Layout Procedure 1) Place the power components first, with ground terminals adjacent (Q2 source, CIN-, COUT-, D1 anode). If possible, make all these connections on the top layer with wide, copper-filled areas. 2) Mount the controller IC adjacent to MOSFET Q2, preferably on the back side opposite Q2 to keep LX, GND, and the DL gate-drive lines short and wide. The DL gate trace must be short and wide, measuring 10 to 20 squares (50 mils to 100 mils wide if the MOSFET is 1in from the controller IC GND pin. 3) Group the gate-drive components (BST diode and capacitor, VDD bypass capacitor) together near the controller IC. MAX8764ETP + 1 OVP V+ 3 OUT 2 FB 4 ILIM THIN QFN Chip Information TRANSISTOR COUNT: 2963 PROCESS: BiCMOS 21 ______________________________________________________________________________________ High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers MAX8764 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.) 22 ______________________________________________________________________________________ QSOP.EPS High-Speed, Step-Down Controller with Accurate Current Limit for Notebook Computers Package Information (continued) (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 MAX8764 D2 D D/2 MARKING k L E/2 E2/2 E (NE-1) X e C L C L b D2/2 0.10 M C A B XXXXX E2 PIN # 1 I.D. DETAIL A e (ND-1) X e e/2 PIN # 1 I.D. 0.35x45 DETAIL B e L1 L C L C L L L e 0.10 C A 0.08 C e C A1 A3 PACKAGE OUTLINE, 16, 20, 28, 32, 40L THIN QFN, 5x5x0.8mm -DRAWING NOT TO SCALE- 21-0140 H 1 2 COMMON DIMENSIONS PKG. 16L 5x5 20L 5x5 28L 5x5 32L 5x5 40L 5x5 SYMBOL MIN. NOM. MAX. MIN. NOM. MAX. MIN. NOM. MAX. MIN. NOM. MAX. MIN. NOM. MAX. EXPOSED PAD VARIATIONS PKG. CODES T1655-1 T1655-2 T1655N-1 T2055-2 T2055-3 T2055-4 T2055-5 T2855-1 T2855-2 T2855-3 T2855-4 T2855-5 T2855-6 T2855-7 T2855-8 T2855N-1 T3255-2 T3255-3 T3255-4 T3255N-1 T4055-1 D2 MIN. NOM. MAX. MIN. E2 NOM. MAX. L 0.15 A A1 A3 b D E e k L L1 N ND NE JEDEC NOTES: DOWN BONDS ALLOWED 0.70 0.75 0.80 0.70 0.75 0.80 0.70 0.75 0.80 0.70 0.75 0.80 0.70 0.75 0.80 0 0.02 0.05 0 0.02 0.05 0 0.02 0.05 0 0.02 0.05 0 0.02 0.05 0.20 REF. 0.20 REF. 0.25 0.30 0.35 0.25 0.30 0.35 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 0.80 BSC. 0.65 BSC. 0.25 - 0.25 0.20 REF. 0.20 REF. 0.20 0.25 0.30 0.20 0.25 0.30 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 4.90 5.00 5.10 0.50 BSC. 0.50 BSC. - 0.25 0.25 0.20 REF. 0.15 0.20 0.25 4.90 5.00 5.10 4.90 5.00 5.10 0.40 BSC. 0.25 0.35 0.45 3.00 3.00 3.00 3.00 3.00 3.00 3.15 3.15 2.60 3.15 2.60 2.60 3.15 2.60 3.15 3.15 3.00 3.00 3.00 3.00 3.20 3.10 3.20 3.00 3.10 3.20 3.00 3.10 3.20 3.00 3.10 3.20 3.00 3.10 3.20 3.00 3.10 3.20 3.00 3.25 3.25 2.70 3.25 2.70 2.70 3.25 2.70 3.25 3.25 3.10 3.10 3.10 3.10 3.35 3.35 2.80 3.35 2.80 2.80 3.35 2.80 3.35 3.35 3.20 3.20 3.20 3.20 3.15 3.15 2.60 3.15 2.60 2.60 3.15 2.60 3.15 3.15 3.00 3.00 3.00 3.00 3.10 3.10 3.10 3.10 3.10 3.10 3.25 3.25 2.70 3.25 2.70 2.70 3.25 2.70 3.25 3.25 3.10 3.10 3.10 3.10 3.30 3.20 3.20 3.20 3.20 3.20 3.20 3.35 3.35 2.80 3.35 2.80 2.80 3.35 2.80 3.35 3.35 3.20 3.20 3.20 3.20 3.40 ** ** ** ** ** ** 0.40 ** ** ** ** ** ** ** 0.40 ** ** ** ** ** ** NO YES NO NO YES NO YES NO NO YES YES NO NO YES YES NO NO YES NO NO YES 0.30 0.40 0.50 0.45 0.55 0.65 0.45 0.55 0.65 0.30 0.40 0.50 0.40 0.50 0.60 - 0.30 0.40 0.50 16 4 4 WHHB 20 5 5 WHHC 28 7 7 WHHD-1 32 8 8 WHHD-2 40 10 10 ----- 1. DIMENSIONING & TOLERANCING CONFORM TO ASME Y14.5M-1994. 2. ALL DIMENSIONS ARE IN MILLIMETERS. ANGLES ARE IN DEGREES. 3. N IS THE TOTAL NUMBER OF TERMINALS. 4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL CONFORM TO JESD 95-1 SPP-012. DETAILS OF TERMINAL #1 IDENTIFIER ARE OPTIONAL, BUT MUST BE LOCATED WITHIN THE ZONE INDICATED. THE TERMINAL #1 IDENTIFIER MAY BE EITHER A MOLD OR MARKED FEATURE. 5. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.25 mm AND 0.30 mm FROM TERMINAL TIP. 6. ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE RESPECTIVELY. 7. DEPOPULATION IS POSSIBLE IN A SYMMETRICAL FASHION. 8. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS. 9. DRAWING CONFORMS TO JEDEC MO220, EXCEPT EXPOSED PAD DIMENSION FOR T2855-1, T2855-3, AND T2855-6. 10. WARPAGE SHALL NOT EXCEED 0.10 mm. 11. MARKING IS FOR PACKAGE ORIENTATION REFERENCE ONLY. 12. NUMBER OF LEADS SHOWN ARE FOR REFERENCE ONLY. 13. LEAD CENTERLINES TO BE AT TRUE POSITION AS DEFINED BY BASIC DIMENSION "e", 0.05. 3.30 3.40 3.20 ** SEE COMMON DIMENSIONS TABLE PACKAGE OUTLINE, 16, 20, 28, 32, 40L THIN QFN, 5x5x0.8mm -DRAWING NOT TO SCALE- 21-0140 H 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. 23 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 (c) 2005 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products, Inc. |
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