19-3355; Rev 0; 8/04 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers The MAX8732 features a 200kHz/5V and 300kHz/3.3V SMPS for highest efficiency, while the MAX8733 features a 400kHz/5V and 500kHz/3.3V SMPS for “thin and light” applications. The MAX8734 provides a pin-selectable switching frequency, allowing either 200kHz/300kHz or 400kHz/500kHz operation of the 5V/3.3V SMPSs, respectively. The MAX8732/MAX8733/MAX8734 are available in 28-pin QSOP packages and operate over the extended temperature range (-40°C to +85°C). The MAX8732/MAX8733/MAX8734 are pin-for-pin upgrades to the MAX1777/MAX1977/MAX1999. The MAX1999 Evaluation Kit can be used to evaluate the MAX8732/MAX8733/MAX8734. Applications Notebook and Subnotebook Computers Features ♦ No Current-Sense Resistor Needed (MAX8734) ♦ Accurate Current Sense with Current-Sense Resistor (MAX8732/MAX8733) ♦ 1.5% Output Voltage Accuracy ♦ 3.3V and 5V 100mA Bootstrapped Linear Regulators ♦ Internal Soft-Start and Soft-Stop Output Discharge ♦ Quick-PWM with 100ns Load Step Response ♦ 3.3V and 5V Fixed or Adjustable Outputs (Dual Mode™) ♦ 4.5V to 24V Input Voltage Range ♦ Enhanced Ultrasonic Pulse-Skipping Mode (25kHz min) ♦ Power-Good (PGOOD) Signal ♦ Overvoltage Protection Enable/Disable Ordering Information MAX8732EEI -40°C to +85°C 28 QSOP 5V/3V SWITCHING FREQUENCY 200kHz/300kHz MAX8733EEI -40°C to +85°C 28 QSOP 400kHz/500kHz MAX8734EEI -40°C to +85°C 28 QSOP 200kHz/300kHz or 400kHz/500kHz PART TEMP RANGE PINPACKAGE Pin Configurations TOP VIEW N.C. 1 28 BST3 PGOOD 2 27 LX3 ON3 3 26 DH3 ON5 4 25 LDO3 ILIM3 5 SHDN 6 24 DL3 MAX8734 23 GND PDAs and Mobile Communication Devices FB3 7 22 OUT3 3- and 4-Cell Li+ Battery-Powered Devices REF 8 21 OUT5 FB5 9 20 V+ PRO 10 19 DL5 ILIM5 11 18 LDO5 SKIP 12 17 VCC TON 13 16 DH5 BST5 14 15 LX5 Quick-PWM and Dual Mode are trademarks of Maxim Integrated Products, Inc. QSOP Pin Configurations continued at end of data sheet. ________________________________________________________________ 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 MAX8732/MAX8733/MAX8734 General Description The MAX8732/MAX8733/MAX8734 dual step-down, switch-mode power-supply (SMPS) controllers generate logic-supply voltages in battery-powered systems. The MAX8732/MAX8733/MAX8734 include two pulse-width modulation (PWM) controllers, adjustable from 2V to 5.5V or fixed at 5V and 3.3V. These devices feature two linear regulators providing 5V and 3.3V always-on outputs. Each linear regulator provides up to 100mA output current with automatic linear-regulator bootstrapping to the main SMPS outputs. The MAX8732/MAX8733/MAX8734 include on-board power-up sequencing, a power-good (PGOOD) output, digital soft-start, and internal soft-stop output discharge that prevents negative voltages on shutdown. Maxim’s proprietary Quick-PWM™ quick-response, constant on-time PWM control scheme operates without sense resistors and provides 100ns response to load transients while maintaining a relatively constant switching frequency. The unique ultrasonic pulse-skipping mode maintains the switching frequency above 25kHz, which eliminates noise in audio applications. Other features include pulse skipping, which maximizes efficiency in light-load applications, and fixed-frequency PWM mode, which reduces RF interference in sensitive applications. MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers ABSOLUTE MAXIMUM RATINGS V+, SHDN to GND ..................................................-0.3V to +25V BST_ to GND ..........................................................-0.3V to +30V LX_ to BST_ ..............................................................-6V to +0.3V CS_ to GND (MAX8732/MAX8733 only)......................-2V to +6V VCC, LDO5, LDO3, OUT3, OUT5, ON3, ON5, REF, FB3, FB5, SKIP, PRO, PGOOD to GND ...............-0.3V to +6V DH3 to LX3 ..............................................-0.3V to (VBST3 + 0.3V) DH5 to LX5 ..............................................-0.3V to (VBST5 + 0.3V) ILIM3, ILIM5 to GND...................................-0.3V to (VCC + 0.3V) DL3, DL5 to GND....................................-0.3V to (VLDO5 + 0.3V) TON to GND (MAX8734 only)...................................-0.3V to +6V LDO3, LDO5, REF Short Circuit to GND ....................Momentary LDO3 Current (Internal Regulator) Continuous ..............+100mA LDO3 Current (Switched Over to OUT3) Continuous.....+200mA LDO5 Current (Internal Regulator) Continuous ..............+100mA LDO5 Current (Switched Over to OUT5) Continuous.....+200mA Continuous Power Dissipation (TA = +70°C) 28-Pin QSOP (derate 10.8mW/°C above +70°C).........860mW 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 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, V SHDN = 5V, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER CONDITIONS MIN TYP MAX UNITS MAIN SMPS CONTROLLERS V+ Input Voltage Range 3.3V Output Voltage in Fixed Mode 5V Output Voltage in Fixed Mode LDO5 in regulation V+ = LDO5, VOUT5 < 4.43V V+ = 6V to 24V, FB3 = GND, V SKIP = 5V V+ = 6V to 24V, FB5 = GND, V SKIP = 5V, MAX8732/MAX8734 (TON = VCC) 6 24 4.5 5.5 V 3.285 3.330 3.375 V 4.975 5.050 5.125 V 1.975 2.00 2.025 V V+ = 7V to 24V, FB5 = GND, V SKIP = 5V, MAX8733/MAX8734 (TON = GND) Output Voltage in Adjustable Mode V+ = 6V to 24V, either SMPS Output Voltage Adjust Range Either SMPS 2.0 5.5 V FB3, FB5 Adjustable-Mode Threshold Voltage Dual-Mode comparator 0.1 0.2 V DC Load Regulation Either SMPS, V SKIP = 5V, 0 to 5A -0.1 Either SMPS, SKIP = GND, 0 to 5A -1.5 Either SMPS, V SKIP = 2V, 0 to 5A Line Regulation Either SMPS, 6V < V+ < 24V Current-Limit Threshold (Positive, Default) ILIM_ = VCC, GND - CS_ (MAX8732/MAX8733), GND - LX_ (MAX8734) Current-Limit Threshold (Positive, Adjustable) GND - CS_ (MAX8732/MAX8733), GND - LX_ (MAX8734) -1.7 0.005 93 100 %/V 107 VILIM_ = 0.5V 40 50 60 VILIM_ = 1V 93 100 107 VILIM_ = 2V 185 200 215 Zero-Current Threshold SKIP = GND, ILIM_ = VCC, GND - CS_ (MAX8732/MAX8733), GND - LX_ (MAX8734) Current-Limit Threshold (Negative, Default) SKIP = ILIM_ = VCC, GND - CS_ (MAX8732/MAX8733), GND - LX_ (MAX8734) Soft-Start Ramp Time Zero to full limit 2 % mV mV 3 mV -120 mV 1.7 ms _______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, V SHDN = 5V, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER Operating Frequency CONDITIONS 5V SMPS 200 3.3V SMPS 300 MAX8733 or MAX8734 (VTON = 0), SKIP = VCC 5V SMPS 400 MAX8732 or MAX8734 (VTON = 5V) MAX8733 or MAX8734 (VTON = 0) 3.3V SMPS MAX8732 or MAX8734 (VTON = 5V) MAX8733 or MAX8734 (VTON = 0) MAX 500 36 VOUT5 = 5.05V 1.895 2.105 2.315 VOUT3 = 3.33V 0.833 0.925 1.017 VOUT5 = 5.05V 0.895 1.052 1.209 VOUT3 = 3.33V 0.475 0.555 0.635 250 300 350 VOUT5 = 5.05V 94 VOUT3 = 3.33V 91 VOUT5 = 5.05V 88 VOUT3 = 3.33V INTERNAL REGULATOR AND REFERENCE LDO5 Output Voltage ON3 = ON5 = GND, 6V < V+ < 24V, 0 < ILDO5 < 100mA UNITS kHz 25 Minimum Off-Time Maximum Duty Cycle TYP MAX8732 or MAX8734 (VTON = 5V), SKIP = VCC SKIP = REF On-Time Pulse Width MIN µs ns % 85 4.90 5.00 5.10 LDO5 Short-Circuit Current LDO5 = GND LDO5 Undervoltage-Lockout Fault Threshold Falling edge of LDO5, hysteresis = 1% 3.7 4.0 4.3 V LDO5 Bootstrap Switch Threshold Falling edge of OUT5, rising edge at OUT5 regulation point 4.43 4.56 4.69 V LDO5 Bootstrap Switch Resistance LDO5 to OUT5, VOUT5 = 5V 1.4 3.2 Ω 3.35 3.42 LDO3 Output Voltage ON3 = ON5 = GND, 6V < V+ < 24V, 0 < ILDO3 < 100mA LDO3 Short-Circuit Current LDO3 = GND LDO3 Bootstrap Switch Threshold Falling edge of OUT3, rising edge at OUT3 regulation point LDO3 Bootstrap Switch Resistance LDO3 to OUT3, VOUT3 = 3.2V REF Output Voltage No external load REF Load Regulation 0 < ILOAD < 50µA REF Sink Current REF in regulation V+ Operating Supply Current LDO5 switched over to OUT5, 5V SMPS V+ Standby Supply Current V+ = 6V to 24V, both SMPSs off, includes ISHDN 190 V 3.28 mA 180 2.80 1.980 V mA 2.91 3.02 V 1.5 3.5 Ω 2.000 2.020 V 10 mV 25 50 µA 150 250 µA 10 µA V+ Shutdown Supply Current V+ = 4.5V to 24V 6 15 µA Quiescent Power Consumption Both SMPSs on, FB3 = FB5 = SKIP = GND, VOUT3 = 3.5V, VOUT5 = 5.3V 3 4.5 mW +11 +14 % FAULT DETECTION Overvoltage Trip Threshold FB3 or FB5 with respect to nominal regulation point +8 _______________________________________________________________________________________ 3 MAX8732/MAX8733/MAX8734 ELECTRICAL CHARACTERISTICS (continued) MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, V SHDN = 5V, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER CONDITIONS Overvoltage Fault Propagation Delay FB3 or FB5 delay with 50mV overdrive PGOOD Threshold FB3 or FB5 with respect to nominal output, falling edge, typical hysteresis = 1% PGOOD Propagation Delay Falling edge, 50mV overdrive PGOOD Output Low Voltage ISINK = 4mA PGOOD Leakage Current High state, forced to 5.5V MIN TYP MAX 10 -12 -9.5 µs -7 10 Thermal-Shutdown Threshold UNITS % µs 0.3 V 1 µA o +160 C Output Undervoltage Shutdown Threshold FB3 or FB5 with respect to nominal output voltage 65 70 75 % Output Undervoltage Shutdown Blanking Time From ON_ signal 10 22 35 ms -200 +40 +200 nA INPUTS AND OUTPUTS Feedback Input Leakage Current PRO Input Voltage VFB3 = VFB5 = 2.2V Low level High level 0.6 1.5 Low level SKIP Input Voltage TON Input Voltage 0.8 Float level 1.7 High level 2.4 2.3 Low level High level 0.8 2.4 Clear fault level/SMPS off level ON3, ON5 Input Voltage Input Leakage Current SHDN Input Trip Level 1.7 SMPS on level 2.4 V PRO or VTON = 0 or 5V -1 +1 VON_ = 0 or 5V -2 +2 V SKIP = 0 or 5V -1 +1 V SHDN = 0 or 24V -1 +1 2.3 -2 +2 VILIM3, VILIM5 = 0 or 2V -0.2 +0.2 Rising edge 1.2 1.6 2.0 Falling edge 0.96 1.00 1.04 DH_ Gate-Driver Sink/Source Current DH3, DH5 forced to 2V DL_ Gate-Driver Source Current V V 0.8 Delay start level VCS_ = 0 or 5V V V µA V 2 A DL3 (source), DL5 (source), forced to 2V 1.7 A DL_ Gate-Driver Sink Current DL3 (sink), DL5 (sink), forced to 2V 3.3 DH_ Gate-Driver On-Resistance BST - LX_ forced to 5V 1.5 4.0 DL_, high state (pullup) 2.2 5.0 DL_, low state (pulldown) 0.6 1.5 DL_ Gate-Driver On-Resistance 4 _______________________________________________________________________________________ A Ω Ω High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, V SHDN = 5V, TA = 0°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) PARAMETER CONDITIONS MIN OUT3, OUT5 Discharge-Mode On-Resistance OUT3, OUT5 Discharge-Mode Synchronous Rectifier Turn-On Level 0.2 TYP MAX UNITS 12 40 Ω 0.3 0.4 V ELECTRICAL CHARACTERISTICS (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, V SHDN = 5V, TA = -40°C to +85°C, unless otherwise noted.) (Note 1) PARAMETER CONDITIONS MIN TYP MAX UNITS MAIN SMPS CONTROLLERS V+ Input Voltage Range 3.3V Output Voltage in Fixed Mode 5V Output Voltage in Fixed Mode LDO5 in regulation 6 24 V+ = LDO5, VOUT5 < 4.41V 4.5 5.5 V+ = 6V to 24V, FB3 = GND, V SKIP = 5V 3.27 3.39 V 4.95 5.15 V V+ = 6V to 24V, FB5 = GND, V SKIP = 5V, MAX8732/MAX8734 (TON = VCC) V V+ = 7V to 24V, FB5 = GND, V SKIP = 5V, MAX8733/MAX8734 (TON = GND) Output Voltage in Adjustable Mode V+ = 6V to 24V, either SMPS 1.97 2.03 V Output Voltage Adjust Range Either SMPS 2.0 5.5 V FB3, FB5 Adjustable-Mode Threshold Voltage Dual-Mode comparator 0.1 0.2 V Current-Limit Threshold (Positive, Default) ILIM_ = VCC, GND - CS_ (MAX8732/MAX8733), GND - LX_ (MAX8734) 90 110 mV Current-Limit Threshold (Positive, Adjustable) GND - CS_ (MAX8732/MAX8733), GND - LX_ (MAX8734) MAX8732 or MAX8734 (VTON = 5V) On-Time Pulse Width MAX8733 or MAX8734 (VTON = 0) VILIM_ = 0.5V 40 60 VILIM_ = 1V 90 110 VILIM_ = 2V 180 220 VOUT5 = 5.05V 1.895 2.315 VOUT3 = 3.33V 0.833 1.017 VOUT5 = 5.05V 0.895 1.209 VOUT3 = 3.33V 0.475 0.635 200 400 ns Minimum Off-Time mV µs INTERNAL REGULATOR AND REFERENCE LDO5 Output Voltage ON3 = ON5 = GND, 6V < V+ < 24V, 0 < ILDO5 < 100mA 4.90 5.10 V LDO5 Undervoltage-Lockout Fault Threshold Falling edge of LDO5, hysteresis = 1% 3.7 4.3 V _______________________________________________________________________________________ 5 MAX8732/MAX8733/MAX8734 ELECTRICAL CHARACTERISTICS (continued) MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers ELECTRICAL CHARACTERISTICS (continued) (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12.0.V, ON3 = ON5 = VCC, V SHDN = 5V, TA = -40°C to +85°C, unless otherwise noted.) (Note 1) PARAMETER CONDITIONS Falling edge of OUT5, rising edge at OUT5 regulation LDO5 Bootstrap Switch Threshold point MIN TYP 4.43 MAX UNITS 4.69 V 3.2 Ω LDO5 Bootstrap Switch Resistance LDO5 to OUT5, VOUT5 = 5V LDO3 Output Voltage ON3 = ON5 = GND, 6V < V+ < 24V, 0 < ILDO3 < 100mA 3.27 3.43 V LDO3 Bootstrap Switch Threshold Falling edge of OUT3, rising edge at OUT3 regulation point 2.80 3.02 V LDO3 Bootstrap Switch Resistance LDO3 to OUT3, VOUT3 = 3.2V 3.5 Ω REF Output Voltage No external load REF Load Regulation 0 < ILOAD < 50µA REF Sink Current REF in regulation 1.975 2.025 V 10 mV 10 µA V+ Operating Supply Current LDO5 switched over to OUT5, 5V SMPS 50 µA V+ Standby Supply Current V+ = 6V to 24V, both SMPSs off, includes ISHDN 300 µA V+ Shutdown Supply Current V+ = 4.5V to 24V 15 µA Quiescent Power Consumption Both SMPSs on, FB3 = FB5 = SKIP = GND, VOUT3 = 3.5V, VOUT5 = 5.3V 4.5 mW FAULT DETECTION Overvoltage Trip Threshold FB3 or FB5 with respect to nominal regulation point +8 +14 % PGOOD Threshold FB3 or FB5 with respect to nominal output, falling edge, typical hysteresis = 1% -12 -7 % PGOOD Output Low Voltage ISINK = 4mA PGOOD Leakage Current High state, forced to 5.5V Output Undervoltage Shutdown Threshold FB3 or FB5 with respect to nominal output voltage Output Undervoltage Shutdown Blanking Time From ON_ signal 0.3 V 1 µA 65 75 % 10 40 ms -200 +200 nA INPUTS AND OUTPUTS Feedback Input Leakage Current PRO Input Voltage VFB3 = VFB5 = 2.2V Low level High level 0.6 1.5 Low level SKIP Input Voltage TON Input Voltage 6 0.8 Float level 1.7 High level 2.4 Low level High level V 2.3 0.8 2.4 _______________________________________________________________________________________ V V High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12.0.V, ON3 = ON5 = VCC, V SHDN = 5V, TA = -40°C to +85°C, unless otherwise noted.) (Note 1) PARAMETER CONDITIONS MIN Clear fault level/SMPS off level ON3, ON5 Input Voltage Input Leakage Current DH_ Gate-Driver On-Resistance DL_ Gate-Driver On-Resistance MAX 1.7 SMPS on level 2.4 V PRO or VTON = 0 or 5V -1 +1 VON_ = 0 or 5V -1 +1 V SKIP = 0 or 5V -2 +2 V SHDN = 0 or 24V -1 +1 2.3 -2 +2 VILIM3, VILIM5 = 0 or 2V -0.2 +0.2 Rising edge 1.2 2.0 Falling edge 0.96 1.04 BST - LX_ forced to 5V 4.0 DL_, high state (pullup) 5.0 DL_, low state (pulldown) 1.5 OUT3, OUT5 Discharge-Mode On-Resistance OUT3, OUT5 Discharge-Mode Synchronous Rectifier Turn-On Level UNITS 0.8 Delay start level VCS_ = 0 or 5V SHDN Input Trip Level TYP 0.2 V µA V Ω Ω 40 Ω 0.4 V Note 1: Specifications to -40°C are guaranteed by design, not production tested. _______________________________________________________________________________________ 7 MAX8732/MAX8733/MAX8734 ELECTRICAL CHARACTERISTICS (continued) Typical Operating Characteristics (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, SHDN = V+, RCS = 7mΩ, VILIM_ = 0.5V, TA = +25°C, unless otherwise noted.) 5V OUTPUT EFFICIENCY vs. LOAD CURRENT (MAX8733) E B F D 50 40 A: IDLE MODE, VIN = 7V B: IDLE MODE, VIN = 12V C: IDLE MODE, VIN = 24V D: PWM MODE, VIN = 7V E: PWM MODE, VIN = 12V F: PWM MODE, VIN = 24V 30 20 10 0.01 0.1 1 0.01 1 D 40 A: IDLE MODE, VIN = 7V B: IDLE MODE, VIN = 12V C: IDLE MODE, VIN = 24V D: PWM MODE, VIN = 7V E: PWM MODE, VIN = 12V F: PWM MODE, VIN = 24V B 30 20 F 10 0 10 0.001 0.01 0.1 1 10 PWM NO-LOAD BATTERY CURRENT vs. INPUT VOLTAGE IDLE MODE™ NO-LOAD BATTERY CURRENT vs. INPUT VOLTAGE F 0 0.001 0.01 0.1 1 34 MAX8733 32 30 28 MAX8732 26 10 13 16 19 22 MAX8732/3/4 toc07 178 MAX8733 174 172 25 10.0 9.5 9.0 8.5 MAX8732 8.0 MAX8733 7.5 7.0 6.5 6.0 13 16 19 22 25 MAX8732/3/4 toc06 10 13 16 19 22 25 250 225 VIN = 7V 200 175 PWM MODE 150 125 100 75 50 ULTRASONIC MODE 25 5.0 10 7 5V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8732) 5.5 170 MAX8732 0.19 INPUT VOLTAGE (V) SHUTDOWN INPUT CURRENT vs. INPUT VOLTAGE 180 0.22 0.10 7 STANDBY INPUT CURRENT vs. INPUT VOLTAGE MAX8732 MAX8733 0.25 0.13 20 184 0.28 0.16 INPUT VOLTAGE (V) 186 0.31 22 LOAD CURRENT (A) 188 0.34 24 10 190 0.37 BATTERY CURRENT (mA) 36 0.40 MAX8732/3/4 toc09 10 A: IDLE MODE, VIN = 7V B: IDLE MODE, VIN = 12V C: IDLE MODE, VIN = 24V D: PWM MODE, VIN = 7V E: PWM MODE, VIN = 12V F: PWM MODE, VIN = 24V 38 SWITCHING FREQUENCY (kHz) D B 40 BATTERY CURRENT (mA) MAX8732/3/4 toc04 E 7 E 50 3.3V OUTPUT EFFICIENCY vs. LOAD CURRENT (MAX8733) 20 7 10 INPUT VOLTAGE (V) 8 0.1 C 60 LOAD CURRENT (A) SHUTDOWN INPUT CURRENT (µA) EFFICIENCY (%) 0.001 A 70 LOAD CURRENT (A) 50 176 A: IDLE MODE, VIN = 7V B: IDLE MODE, VIN = 12V C: IDLE MODE, VIN = 24V D: PWM MODE, VIN = 7V E: PWM MODE, VIN = 12V F: PWM MODE, VIN = 24V 0 C 182 80 LOAD CURRENT (A) 60 30 40 10 A 40 50 10 90 70 F D 20 100 80 60 30 0 0.001 E B MAX8732/3/4 toc05 60 C 90 70 MAX8732/3/4 toc08 EFFICIENCY (%) 70 A 80 100 EFFICIENCY (%) C 90 MAX8732/3/4 toc02 A 80 100 EFFICIENCY (%) 90 MAX8732/3/4 toc01 100 3.3V OUTPUT EFFICIENCY vs. LOAD CURRENT (MAX8732) MAX8732/3/4 toc03 5V OUTPUT EFFICIENCY vs. LOAD CURRENT (MAX8732) STANDBY INPUT CURRENT (µA) MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers 13 16 19 INPUT VOLTAGE (V) 22 25 0 0.001 PFM MODE 0.01 0.1 LOAD CURRENT (A) _______________________________________________________________________________________ Idle Mode is a trademark of Maxim Integrated Products, Inc. 1 10 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers 160 120 125 100 75 50 ULTRASONIC MODE 40 ULTRASONIC MODE 25 PFM MODE PFM MODE 0 0.01 0.1 1 0.001 10 0.01 350 300 250 200 150 100 0.001 0.01 0.1 1 VIN = 7V PWM MODE 450 400 350 300 ULTRASONIC MODE 250 200 150 0.001 VIN = 24V 550 500 350 300 250 200 ULTRASONIC MODE 0.01 0 0.001 1 LOAD CURRENT (A) 1 10 MAX8732/3/4 toc12 10 PWM MODE 350 300 250 200 ULTRASONIC MODE 150 100 PFM MODE 0.001 0.01 ULTRASONIC 5.17 5.13 IDLE MODE 5.09 5.05 0.001 1 10 OUT3 VOLTAGE REGULATION vs. LOAD CURRENT (MAX8732) 5.15 5.11 0.1 LOAD CURRENT (A) 3.41 ULTRASONIC 3.40 3.39 3.38 IDLE MODE 3.37 3.36 FORCED-PWM 3.35 3.34 IDLE MODE 0.1 400 10 5.07 0.01 1 VIN = 24V 0 0.1 FORCED-PWM 100 0.1 450 PFM MODE 5.19 OUTPUT VOLTAGE (V) PWM MODE 50 0.01 500 OUT5 VOLTAGE REGULATION vs. LOAD CURRENT (MAX8732) MAX8732/3/4 toc16 600 150 PFM MODE LOAD CURRENT (A) 3.3V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8733) 450 ULTRASONIC MODE 50 0 0.001 LOAD CURRENT (A) 400 80 5V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8733) 500 10 120 3.3V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8733) 50 IDLE MODE 160 LOAD CURRENT (A) 550 0 200 10 100 50 SWITCHING FREQUENCY (kHz) 1 OUTPUT VOLTAGE (V) SWITCHING FREQUENCY (kHz) PWM MODE 400 0.1 600 SWITCHING FREQUENCY (kHz) VIN = 7V 450 MAX8732/3/4 toc13 500 240 LOAD CURRENT (A) LOAD CURRENT (A) 5V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8733) PWM MODE 280 0 SWITCHING FREQUENCY (kHz) 0 0.001 320 40 MAX8732/3/4 toc14 80 150 VIN = 24V 360 MAX8732/3/4 toc15 200 175 400 MAX8732/3/4 toc18 240 PWM MODE 200 3.3V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8732) SWITCHING FREQUENCY (kHz) PWM MODE MAX8732/3/4 toc17 SWITCHING FREQUENCY (kHz) 280 VIN = 24V 225 SWITCHING FREQUENCY (kHz) VIN = 7V 320 250 MAX8732/3/4 toc10 360 MAX8732/3/4 toc11 5V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8732) 3.3V OUTPUT SWITCHING FREQUENCY vs. LOAD CURRENT (MAX8732) 0.01 0.1 LOAD CURRENT (A) 1 10 3.33 0.001 0.01 0.1 1 10 LOAD CURRENT (A) _______________________________________________________________________________________ 9 MAX8732/MAX8733/MAX8734 Typical Operating Characteristics (continued) (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, SHDN = V+, RCS = 7mΩ, VILIM_ = 0.5V, TA = +25°C, unless otherwise noted.) Typical Operating Characteristics (continued) (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, SHDN = V+, RCS = 7mΩ, VILIM_ = 0.5V, TA = +25°C, unless otherwise noted.) 4.97 4.96 4.95 3.348 2.005 3.346 2.004 2.003 3.344 2.002 3.342 2.001 VREF (V) 4.98 REFERENCE VOLTAGE vs. OUTPUT CURRENT MAX8732/3/4 toc20 4.99 3.350 LDO3 OUTPUT VOLTAGE (V) MAX8732/3/4 toc19 5.00 LDO3 REGULATOR OUTPUT VOLTAGE vs. OUTPUT CURRENT 3.340 2.000 3.338 1.999 3.336 1.998 3.334 1.997 3.332 1.996 3.330 0 10 20 30 40 50 60 70 80 90 100 MAX8732/3/4 toc21 LDO5 REGULATOR OUTPUT VOLTAGE vs. OUTPUT CURRENT LDO5 OUTPUT VOLTAGE (V) MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers 1.995 0 10 20 30 40 50 60 70 80 90 100 -10 0 10 20 30 40 50 60 70 80 90 100 LDO5 OUTPUT CURRENT (mA) LDO3 OUTPUT CURRENT (mA) IREF (µA) REF, LDO3, AND LDO5 POWER-UP DELAYED START WAVEFORMS (ON5 = REF) DELAYED START WAVEFORMS (ON3 = REF) MAX8732/3/4 toc23 MAX8732/3/4 toc22 V+ 10V/div 10V 5V ON5 2V/div LDO5 2V/div 0 LDO3 2V/div 0 3.3V REF 1V/div ON3 2V/div 0 3.3V OUT3 2V/div 0 0 MAX8732/3/4 toc24 5V 0 5V OUT3 2V/div 0 5V OUT5 2V/div 0 0 0 200µs/div 200µs/div SHUTDOWN WAVEFORMS MAX8732/MAX8734 (TON = VCC) 5V PWM-MODE LOAD TRANSIENT RESPONSE 400µs/div SOFT-START WAVEFORMS MAX8732/3/4 toc25 5A MAX8732/3/4 toc26 IL5 5A/div 0 IL3 5A/div 5A 0 3.3V OUT3 5V/div 0 5V OUT5 5V/div 0 200µs/div 10 OUT5 2V/div 5V MAX8732/3/4 toc27 ON3 5V/div 0 3.3V 0 OUT3 5V/div 5V OUT5 5V/div 0 5V SWITCHING VOUT, ACCOUPLED 100mV/div 5V 4A INDUCTOR CURRENT 2A/div 1A 5V DL3 5V/div 0 10ms/div DL5 5V/div 0 20µs/div ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers MAX8733/MAX8734 (TON = GND) 3.3V PWM-MODE LOAD TRANSIENT RESPONSE MAX8732/MAX8734 (TON = VCC) 3.3V PWM-MODE LOAD TRANSIENT RESPONSE MAX8733/MAX8734 (TON = GND) 5V PWM-MODE LOAD TRANSIENT RESPONSE MAX8732/3/4 toc28 MAX8732/3/4 toc29 VOUT, ACCOUPLED 100mV/div 5V 4A 1A VOUT, ACCOUPLED 100mV/div 3.3V INDUCTOR CURRENT 2A/div 5V MAX8732/3/4 toc30 4A INDUCTOR CURRENT 2A/div 1A 5V DL5 5V/div 0 0 5V ULTRASONIC EFFICIENCY vs. LOAD CURRENT (TON = GND) 100 VIN = 24V 50 40 80 VIN = 24V 70 60 50 40 30 30 20 20 10 10 0.01 0.1 1 0 0.001 10 0.01 0.1 1 LOAD CURRENT (A) LOAD CURRENT (A) 3.3V ULTRASONIC EFFICIENCY vs. LOAD CURRENT (TON = VCC) 3.3V ULTRASONIC EFFICIENCY vs. LOAD CURRENT (TON = GND) 90 80 80 EFFICIENCY (%) VIN = 7V 60 VIN = 12V 50 40 VIN = 24V 30 70 50 30 20 10 LOAD CURRENT (A) VIN = 24V 40 10 0.1 VIN = 12V 60 20 0.01 VIN = 7V 90 10 MAX8732/3/4 toc34 100 MAX8732/3/4 toc33 100 EFFICIENCY (%) VIN = 12V 90 EFFICIENCY (%) EFFICIENCY (%) VIN = 12V 60 0 0.001 DL3 5V/div 0 MAX8732/3/4 toc32 90 70 1A 10µs/div MAX8732/3/4 toc31 100 0 0.001 INDUCTOR CURRENT 2A/div 20µs/div 5V ULTRASONIC EFFICIENCY vs. LOAD CURRENT (TON = VCC) 70 4A 5V DL3 5V/div 10µs/div 80 VOUT, ACCOUPLED 100mV/div 3.3V 1 10 0 0.001 0.01 0.1 1 10 LOAD CURRENT (A) ______________________________________________________________________________________ 11 MAX8732/MAX8733/MAX8734 Typical Operating Characteristics (continued) (Circuit of Figure 1 and Figure 2, no load on LDO5, LDO3, OUT3, OUT5, and REF, V+ = 12V, ON3 = ON5 = VCC, SHDN = V+, RCS = 7mΩ, VILIM_ = 0.5V, TA = +25°C, unless otherwise noted.) MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers Pin Description PIN MAX8732 MAX8734 MAX8733 12 NAME 1 — CS3 — 1 N.C. 2 2 PGOOD 3 3 ON3 4 4 ON5 5 5 ILIM3 6 6 SHDN 7 7 FB3 8 8 REF 9 9 FB5 10 10 PRO 11 11 ILIM5 12 12 SKIP FUNCTION 3.3V SMPS Current-Sense Input. Connect CS3 to a current-sensing resistor from the source of the synchronous rectifier to GND. The voltage at ILIM3 determines the current-limit threshold (see the Current-Limit (ILIM) Circuit section). No Connection. Not internally connected. Power-Good Output. PGOOD is an open-drain output that is pulled low if either output is disabled or is more than 10% below its nominal value. 3.3V SMPS Enable Input. The 3.3V SMPS is enabled if ON3 is greater than the SMPS on level and disabled if ON3 is less than the SMPS off level. If ON3 is connected to REF, the 3.3V SMPS starts after the 5V SMPS reaches regulation (delay start). Drive ON3 below the clear fault level to reset the fault latches. 5V SMPS Enable Input. The 5V SMPS is enabled if ON5 is greater than the SMPS on level and disabled if ON5 is less than the SMPS off level. If ON5 is connected to REF, the 5V SMPS starts after the 3.3V SMPS reaches regulation (delay start). Drive ON5 below the clear fault level to reset the fault latches. 3.3V SMPS Current-Limit Adjustment. The GND-LX current-limit threshold defaults to 100mV if ILIM3 is connected to VCC. In adjustable mode, the current-limit threshold is 1/10th the voltage seen at ILIM3 over a 0.5V to 3V range. The logic threshold for switchover to the 100mV default value is approximately VCC - 1V. Connect ILIM3 to REF for a fixed 200mV threshold. Shutdown Control Input. The device enters its 6µA 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 V+ for automatic startup. SHDN can be connected to V+ through a resistive voltage-divider to implement a programmable undervoltage lockout. 3.3V SMPS Feedback Input. Connect FB3 to GND for fixed 3.3V operation. Connect FB3 to a resistive voltage-divider from OUT3 to GND to adjust the output from 2V to 5.5V. 2V Reference Output. Bypass to GND with a 0.22µF (min) capacitor. REF can source up to 100µA for external loads. Loading REF degrades FB_ and output accuracy according to the REF load-regulation error. 5V SMPS Feedback Input. Connect FB5 to GND for fixed 5V operation. Connect FB5 to a resistive voltage-divider from OUT5 to GND to adjust the output from 2V to 5.5V. Overvoltage and Undervoltage Fault Protection Enable/Disable. Connect PRO to VCC to disable undervoltage, overvoltage protection, and discharge mode (DL = low in shutdown). Connect PRO to GND to enable undervoltage and overvoltage protection (see the Fault Protection section), and output discharge mode. 5V SMPS Current-Limit Adjustment. The GND-LX current-limit threshold defaults to 100mV if ILIM5 is connected to VCC. In adjustable mode, the current-limit threshold is 1/10th the voltage seen at ILIM5 over a 0.5V to 3V range. The logic threshold for switchover to the 100mV default value is approximately VCC - 1V. Connect ILIM5 to REF for a fixed 200mV threshold. Low-Noise Mode Control. Connect SKIP to GND for normal Idle-Mode (pulse-skipping) operation or to VCC for PWM mode (fixed frequency). Connect to REF or leave floating for lt i d ( l ki i 25kH i ) ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers PIN MAX8732 MAX8734 MAX8733 NAME 13 — CS5 — 13 TON 14 14 BST5 15 15 LX5 16 16 DH5 17 17 VCC 18 18 LDO5 19 19 DL5 20 20 V+ 21 21 OUT5 22 22 OUT3 23 24 23 24 GND DL3 25 25 LDO3 26 26 DH3 27 27 LX3 28 28 BST3 FUNCTION 5V SMPS Current-Sense Input. Connect CS5 to a current-sensing resistor from the source of the synchronous rectifier to GND. The voltage at ILIM5 determines the current-limit threshold (see the Current-Limit Circuit section). Frequency Select Input. Connect to VCC for 200kHz/300kHz operation and to GND for 400kHz/500kHz operation (5V/3.3V SMPS switching frequencies, respectively). Boost Flying Capacitor Connection for 5V SMPS. Connect to an external capacitor and diode according to the typical application circuits (Figure 1 and Figure 2). See the MOSFET Gate Drivers (DH_, DL_) section. Inductor Connection for 5V SMPS. LX5 is the internal lower supply rail for the DH5 high-side gate driver. LX5 is the current-sense input for the 5V SMPS (MAX8734 only). High-Side MOSFET Floating Gate-Driver Output for 5V SMPS. DH5 swings from LX5 to BST5. Analog Supply Voltage Input for PWM Core. Connect VCC to the system supply voltage with a series 50Ω resistor. Bypass to GND with a 1µF ceramic capacitor. 5V Linear-Regulator Output. LDO5 is the gate-driver supply for the external MOSFETs. LDO5 can provide a total of 100mA, including MOSFET gate-drive requirements and external loads. The internal load depends on the choice of MOSFET and switching frequency (see the Reference and Linear Regulators (REF, LDO5, and LDO3) section). If OUT5 is greater than the LDO5 bootstrap switch threshold, the LDO5 regulator shuts down and the LDO5 pin connects to OUT5 through a 1.4Ω switch. Bypass LDO5 with a minimum of 4.7µF. Use an additional 1µF per 5mA of load. 5V SMPS Synchronous Rectifier Gate-Drive Output. DL5 swings between GND and LDO5. Power-Supply Input. V+ powers the LDO5/LDO3 linear regulators and is also used for the Quick-PWM on-time one-shot circuits. Connect V+ to the battery input through a 4Ω resistor and bypass with a 4.7µF capacitor. 5V SMPS Output Voltage-Sense Input. Connect to the 5V SMPS output. OUT5 is an input to the Quick-PWM on-time one-shot circuit. It also serves as the 5V feedback input in fixed-voltage mode. If OUT5 is greater than the LDO5 bootstrap-switch threshold, the LDO5 linear regulator shuts down and LDO5 connects to OUT5 through a 1.4Ω switch. 3.3V SMPS Output Voltage-Sense Input. Connect to the 3.3V SMPS output. OUT3 is an input to the Quick-PWM on-time one-shot circuit. It also serves as the 3V feedback input in fixedvoltage mode. If OUT3 is greater than the LDO3 bootstrap-switch threshold, the LDO3 linear regulator shuts down and LDO3 connects to OUT3 through a 1.5Ω switch. Analog and Power Ground 3.3V SMPS Synchronous-Rectifier Gate-Drive Output. DL3 swings between GND and LDO5. 3.3V Linear-Regulator Output. LDO3 powers up after REF is in regulation. LDO3 can provide a total of 100mA to external loads. If OUT3 is greater than the LDO3 bootstrap-switch threshold, the LDO3 regulator shuts down and the LDO3 pin connects to OUT3 through a 1.5Ω switch. Bypass LDO3 with a minimum of 4.7µF. Use an additional 1µF per 5mA of load. High-Side MOSFET Floating Gate-Driver Output for 3.3V SMPS. DH3 swings from LX3 to BST3. Inductor Connection for 3.3V SMPS. LX3 is the current-sense input for the 3.3V SMPS (MAX8734 only). Boost Flying Capacitor Connection for 3.3V SMPS. Connect to an external capacitor and diode according to the typical application circuits (Figure 1 and Figure 2). See the MOSFET Gate Drivers (DH_, DL_) section. ______________________________________________________________________________________ 13 MAX8732/MAX8733/MAX8734 Pin Description (continued) MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers Typical Application Circuits Table 1. Component Suppliers The typical application circuits (Figures 1 and 2) generate the 5V/5A and 3.3V/5A main supplies in a notebook computer. The input supply range is 7V to 24V. Table 1 lists component suppliers. Detailed Description The MAX8732/MAX8733/MAX8734 dual-buck, BiCMOS, switch-mode power-supply controllers generate logic supply voltages for notebook computers. The MAX8732/MAX8733/MAX8734 are designed primarily for battery-powered applications where high efficiency and low-quiescent supply current are critical. The MAX8732 is optimized for highest efficiency with a 5V/200kHz SMPS and a 3.3V/300kHz SMPS, while the MANUFACTURER PHONE FACTORY FAX Central Semiconductor 516-435-1110 516-435-1824 Dale-Vishay 402-564-3131 402-563-6418 Fairchild 408-721-2181 408-721-1635 International Rectifier 310-322-3331 310-322-3332 NIEC (Nihon) 805-843-7500 847-843-2798 Sanyo 619-661-6835 619-661-1055 Sprague 603-224-1961 603-224-1430 Sumida 847-956-0666 847-956-0702 Taiyo Yuden 408-573-4150 408-573-4159 TDK 847-390-4461 847-390-4405 VIN 7V TO 24V 5V ALWAYS ON 1µF 4.7µF 50Ω 4Ω LDO5 1µF VCC 0.1µF BST5 BST3 DH5 DH3 10Ω MAX8732 MAX8733 N3 FDS6612A 0.1µF LX5 L3 LX3 C5 3.3V C3 D3 EP10QY03 N2 IRF7811AV DL5 DL3 CS5 CS3 OUT3 OUT5 RCS5 20mΩ FB5 N4 IRF7811AV VCC FB3 100kΩ ON OFF SHDN VCC ON5 REF ON3 D2 EP10QY03 RCS3 20mΩ PGOOD SKIP FREQUENCY-DEPENDENT COMPONENTS 5V/3.3V SMPS SWITCHING FREQUENCY MAX8732 MAX8733 200kHz/300kHz 400kHz/500kHz L3 4.7µH 3.0µH GND REF PRO LDO3 1MΩ 3.3V ALWAYS ON L5 7.6µH 5.6µH C3 470µF 220µF C5 330µF 150µF 0.22µF 4.7µF Figure 1. MAX8732/MAX8733 Typical Application Circuit 14 10µF 10Ω 0.1µF L5 5V 10µF CMPSH-3A 1/2 D1 N1 FDS6612A 1/2 D1 ILIM5 V+ 4.7µF 10µF ILIM3 ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers MAX8732/MAX8733/MAX8734 VIN 7V TO 24V 5V ALWAYS ON 1µF 50Ω 4Ω LDO5 1µF VCC 1/2 D1 ILIM5 V+ 4.7µF 10µF ILIM3 0.1µF 10Ω N1 FDS6612A DH5 N3 FDS6612A DH3 MAX8734 0.1µF 0.1µF L5 LX5 L3 LX3 470pF* C5 10µF BST3 10Ω 5V 10µF CMPSH-3A 1/2 D1 BST5 4.7µF TON D3 EP10QY03 N2 IRF7811AV DL5 DL3 OUT5 OUT3 FB5 470pF* SEE TABLE N4 IRF7811AV 3.3V C3 D2 EP10QY03 VCC FB3 100kΩ ON SHDN OFF VCC ON5 REF ON3 PGOOD SKIP GND REF PRO LDO3 1MΩ 3.3V ALWAYS ON 0.22µF *OPTIONAL CAPACITANCE BETWEEN LX AND PGND (CLOSE TO THE IC) ONLY REQUIRED FOR ULTRASONIC MODE 4.7µF FREQUENCY-DEPENDENT COMPONENTS 5V/3.3V SMPS SWITCHING FREQUENCY TON = VCC TON = GND 200kHz/300kHz 400kHz/500kHz L3 4.7µH 3.0µH L5 7.6µH 5.6µH C3 470µF 220µF C5 330µF 150µF Figure 2. MAX8734 Typical Application Circuit ______________________________________________________________________________________ 15 MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers MAX8733 is optimized for “thin and light” applications with a 5V/400kHz SMPS and a 3.3V/500kHz SMPS. The MAX8734 provides a pin-selectable switching frequency, allowing either 200kHz/300kHz or 400kHz/500kHz operation of the 5V/3.3V SMPSs, respectively. Light-load efficiency is enhanced by automatic IdleMode operation, a variable-frequency pulse-skipping mode that reduces transition and gate-charge losses. Each step-down, power-switching circuit consists of two n-channel MOSFETs, a rectifier, and an LC output filter. The output voltage is the average AC voltage at the switching node, which is regulated by changing the duty cycle of the MOSFET switches. The gate-drive signal to the n-channel high-side MOSFET must exceed the battery voltage, and is provided by a flying-capacitor boost circuit that uses a 100nF capacitor connected to BST_. V+ PGOOD MAX8732 MAX8733 MAX8734 PGOOD3 PGOOD5 TON (MAX8734 ONLY) BST3 BST5 DH3 DH5 LX3 3.3V SMPS PWM CONTROLLER LDO5 LX5 5V SMPS PWM CONTROLLER LDO5 DL5 DL3 CS3 (MAX8732/ MAX8733) CS5 (MAX8732/ MAX8733) ILIM5 ILIM3 FB3 FB5 OUT3 OUT5 EN3 LDO3 4.56V 2.91V EN5 5V LINEAR REG 3V LINEAR REG LDO5 VCC ON3 ON5 POWER-ON SEQUENCE/ CLEAR FAULT LATCH THERMAL SHUTDOWN SHDN 2V REFERENCE PRO REF GND Figure 3. Detailed Functional Diagram 16 ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers controls the power-up timing of the main PWMs and monitors the outputs for undervoltage faults. The MAX8732/MAX8733/MAX8734 include 5V and 3.3V linear regulators. Bias generator blocks include the 5V (LDO5) linear regulator, 2V precision reference, and automatic bootstrap switchover circuit. V+ OUT TON (MAX8734) ON-TIME COMPUTE tOFF TRIG Q ONE SHOT tON TRIG Q R TO DH_ DRIVER ONE SHOT Q REF S ERROR AMPLIFIER ILIM_ CURRENT LIMIT Σ TO DL_ DRIVER CS_ (MAX8732/8733) LX_ (MAX8734) ZERO CROSSING S Q R SKIP OUT_ PGOOD 0.9 ✕ VREF FB_ OV_FAULT UV_FAULT FAULT LATCH 1.1 ✕ VREF 0.15V PRO 20ms BLANKING 0.7✕VREF Figure 4. PWM Controller (One Side Only) ______________________________________________________________________________________ 17 MAX8732/MAX8733/MAX8734 Each PWM controller consists of a Dual-Mode feedback network and multiplexer, a multi-input PWM comparator, high-side and low-side gate drivers, and logic. The MAX8732/MAX8733/MAX8734 contain fault-protection circuits that monitor the main PWM outputs for undervoltage and overvoltage conditions. A power-on sequence block MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers These internal blocks are not powered directly from the battery. Instead, the 5V (LDO5) linear regulator steps down the battery voltage to supply both internal circuitry and the gate drivers. The synchronous-switch gate drivers are directly powered from LDO5, while the highside switch gate drivers are indirectly powered from LDO5 through an external diode-capacitor boost circuit. An automatic bootstrap circuit turns off the 5V linear regulator and powers the device from OUT5 when OUT5 is above 4.56V. Free-Running, Constant On-Time PWM Controller with Input Feed-Forward The Quick-PWM control architecture is a pseudo-fixedfrequency, constant on-time, current-mode type with voltage feedforward. The Quick-PWM control architecture relies on the output ripple voltage to provide the PWM ramp signal; thus the output filter capacitor’s ESR acts as a current-feedback resistor. The high-side switch on-time is determined by a one-shot whose period is inversely proportional to input voltage and directly proportional to output voltage. Another one-shot sets a minimum off-time (300ns typ). The on-time one-shot triggers when the following conditions are met: the error comparator is low, the synchronous rectifier current is below the current-limit threshold, and the minimum offtime one-shot has timed out. On-Time One-Shot (tON) Each PWM core includes a one-shot that sets the highside switch on-time for each controller. Each fast, lowjitter, 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 fixed-frequency clock generator. The benefit of a constant switching frequency is the frequency can be selected to avoid noise-sensitive frequency regions: t ON = K(VOUT + 0.075V ) V+ See Table 2 for approximate K-factors. The constant 0.075V is an approximation to account for the expected drop across the synchronous-rectifier switch. Switching frequency increases as a function of load current due to the increasing drop across the synchronous rectifier, which causes a faster inductor-current discharge ramp. On-times translate only roughly to switching frequencies. The on-times guaranteed in the Electrical Characteristics are influenced by switching delays in the external high-side power MOSFET. Also, the deadtime effect increases the effective on-time, reducing the switching frequency. It occurs only in PWM mode (SKIP = VCC) and during dynamic output voltage transitions 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 on-time by a period equal to the DHrising dead time. For loads above the critical conduction point, the actual switching frequency is: f= VOUT + VDROP1 t ON ( V + + VDROP2 ) 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 parasitic voltage drops in the charging path, including high-side switch, inductor, and PC board resistances, and tON is the on-time calculated by the MAX8732/MAX8733/MAX8734. Automatic Pulse-Skipping Switchover (Idle Mode) In Idle Mode (SKIP = GND), an inherent automatic switchover to PFM takes place at light loads. 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 con- Table 2. Approximate K-Factor Errors SMPS MAX8732/MAX8734 (tON = VCC), 5V MAX8732/MAX8734 (tON = VCC), 3.3V MAX8733/MAX8734 (tON = GND), 5V MAX8733/MAX8734 (tON = GND), 3.3V 18 SWITCHING FREQUENCY (kHz) 200 300 400 500 K-FACTOR (µs) 5.0 3.3 2.5 2.0 APPROXIMATE KFACTOR ERROR (%) ±10 ±10 ±10 ±10 ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers ILOAD(SKIP) = K × VOUT _ V + − VOUT _ 2×L V+ where K is the on-time scale factor (see the On-Time One-Shot (tON) section). The load-current 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 5). For example, in the MAX8732 typical application circuit with VOUT2 = 5V, V+ = 12V, L = 7.6µH, and K = 5µs, switchover to pulse-skipping operation occurs at ILOAD = 0.96A or about 1/5th 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 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 trip level of the error comparator. When the inductor is in continuous conduction, the output voltage has a DC regulation higher than the trip level by 50% of the ripple. In discontinuous conduction (SKIP = GND, light load), the output voltage has a DC regulation higher than the trip level by approximately 1.5% due to slope compensation. Forced-PWM Mode The low-noise, forced-PWM (SKIP = VCC) mode disables the zero-crossing comparator, which controls the ∆i V+ - VOUT = ∆t L INDUCTOR CURRENT -IPEAK ILOAD = IPEAK/2 low-side switch on-time. Disabling the zero-crossing detector causes the low-side, gate-drive waveform to become the complement of the high-side, gate-drive waveform. The inductor current reverses at light loads as the PWM loop strives to maintain a duty ratio of VOUT/V+. 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 50mA, depending on switching frequency and 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. Enhanced Ultrasonic Mode (25kHz (min) Pulse Skipping) Leaving SKIP unconnected or connecting SKIP to REF activates a unique pulse-skipping mode with a minimum switching frequency of 25kHz. This ultrasonic pulse-skipping mode eliminates audio-frequency modulation that would otherwise be present when a lightly loaded controller automatically skips pulses. In ultrasonic mode, the controller automatically transitions to fixed-frequency PWM operation when the load reaches the same critical conduction point (ILOAD(SKIP)) that occurs when normally pulse skipping. An ultrasonic pulse occurs when the controller detects that no switching has occurred within the last 28µs. Once triggered, the ultrasonic controller pulls DL high, turning on the low-side MOSFET to induce a negative inductor current. After the inductor current reaches the negative ultrasonic current threshold, the controller turns off the low-side MOFET (DL pulled low) and triggers a constant on-time (DH driven high). When the ontime has expired, the controller reenables the low-side MOSFET until the controller detects that the inductor current dropped below the zero-crossing threshold. Starting with a DL pulse greatly reduces the peak output voltage when compared to starting with a DH pulse. The output voltage at the beginning of the ultrasonic pulse determines the negative ultrasonic current threshold, resulting in the following equation: VISONIC = IL RON = ( VREF − VFB ) × 0.58 where VFB > VREF and RON is the on-resistance of the synchronous rectifier (MAX8734) or the current-sense resistor value (MAX8732/MAX8733). 0 ON-TIME TIME Figure 5. Pulse- Skipping/Discontinuous Crossover Point ______________________________________________________________________________________ 19 MAX8732/MAX8733/MAX8734 tinuous and discontinuous inductor-current operation (also known as the critical conduction point): Reference and Linear Regulators (REF, LDO5, and LDO3) The 2V reference (REF) is accurate to ±1% over temperature, making REF useful as a precision system reference. Bypass REF to GND with a 0.22µF (min) capacitor. REF can supply up to 100µA for external loads. However, if extremely accurate specifications for both the main output voltages and REF are essential, avoid loading REF. Loading REF reduces the LDO5, LDO3, OUT5, and OUT3 output voltages slightly because of the reference load-regulation error. Two internal regulators produce 5V (LDO5) and 3.3V (LDO3). LDO5 provides gate drive for the external MOSFETs and powers the PWM controller, logic, reference, and other blocks within the device. The LDO5 regulator supplies a total of 100mA for internal and external loads, including MOSFET gate drive, which typically varies from 10mA to 50mA, depending on switching frequency and the external MOSFETs. LDO3 powers up when the reference (REF) is in regulation, and supplies up to 100mA for external loads. Bypass LDO5 and LDO3 with a minimum 4.7µF load; use an additional 1µF per 5mA of internal and external load. When the 5V main output voltage is above the LDO5 bootstrap-switchover threshold, an internal 1.4Ω p-channel MOSFET switch connects OUT5 to LDO5 while simultaneously shutting down the LDO5 linear regulator. Similarly, when the 3.3V main output voltage is above the LDO3 bootstrap-switchover threshold, an internal 1.5Ω p-channel MOSFET switch connects OUT3 to LDO3 while simultaneously shutting down the LDO3 linear regulator. These actions bootstrap the device, powering the internal circuitry and external loads from the output SMPS voltages, rather than through linear regulators from the bat- 40µs (MAX) tery. 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. Current-Limit Circuit (ILIM_) The current-limit circuit employs a “valley” current-sensing algorithm. The MAX8734 uses the on-resistance of the synchronous rectifier, while the MAX8732/MAX8733 use a discrete resistor in series with the source of the synchronous rectifier as a current-sensing element. If the magnitude of the current-sense signal at CS_ (MAX8732/MAX8733)/LX_ (MAX8734) is above the current-limit threshold, the PWM is not allowed to initiate a new cycle (Figure 7). 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 current-limit threshold, inductor value, and input and output voltage. For the MAX8732/MAX8733, connect CS_ to the junction of the synchronous rectifier source and a current-sense resistor to GND. With a current-limit threshold of 100mV, the accuracy is approximately ±7%. Using a lower current-sense threshold results in less accuracy. The current-sense resistor only dissipates power when the synchronous rectifier is on. For lower power dissipation, the MAX8734 uses the onresistance of the synchronous rectifier as the currentsense element. Use the worst-case maximum value for RDS(ON) from the MOSFET data sheet, and add some margin for the rise in RDS(ON) with temperature. A good general rule is to allow 0.5% additional resistance for each °C of temperature rise. The current limit varies with the on-resistance of the synchronous rectifier. The reward for this uncertainty is robust, lossless overcurrent sensing. When combined with the undervoltage- INDUCTOR CURRENT -IPEAK ILOAD ZERO-CROSSING DETECTION 0 INDUCTOR CURRENT MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers ILIMIT ISONIC ON-TIME (tON) 0 TIME Figure 7. “Valley” Current-Limit Threshold Point Figure 6. Ultrasonic Current Waveforms 20 ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers V+ MAX8732 MAX8733 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 signals at CS_. Mount or place the device close to the synchronous rectifier or sense resistor (whichever is used) with short, direct traces, making a Kelvin sense connection to the sense resistor. The current-sense accuracy of Figure 8 is degraded if the Schottky diode conducts during the synchronous rectifier on-time. To ensure that all current passes through the sense resistor, connect the Schottky diode in parallel with only the synchronous recifier (Figure 9) if the voltage drop across the synchronous rectifier and sense resistor exceeds the Schottky diode’s forward voltage. Note that at high temperatures, the on-resistance of the synchronous rectifier increases and the forward voltage of the Schottky diode decreases. MOSFET Gate Drivers (DH_, DL_) DH_ LX_ OUT_ DL_ CS_ Figure 8. Current Sensing Using Sense Resistor (MAX8732/MAX8733) V+ MAX8732 MAX8733 The DH_ and DL_ gate drivers sink 2.0A and 3.3A respectively of gate drive, ensuring robust gate drive for high-current applications. The DH_ floating high-side MOSFET drivers are powered by diode-capacitor charge pumps at BST_. The DL_ synchronous-rectifier drivers are powered by LDO5. The internal pulldown transistors that drive DL_ low have a 0.6Ω typical on-resistance. These low on-resistance pulldown transistors prevent DL_ from being pulled up during the fast rise time of the inductor nodes due to capacitive coupling from the drain to the gate of the low-side synchronous-rectifier MOSFETs. However, for high-current applications, some combinations of high- and low-side MOSFETS may cause excessive gate-drain coupling, which leads to poor efficiency and EMI-producing shoot-through currents. Adding a resistor in series with BST_ increases the turn-on time of the DH_ 5V LX_ OUT_ BST DL_ DH CS_ LX VIN 10Ω MAX8732 MAX8733 MAX8734 Figure 9. More Accurate Current Sensing with Adjusted Schottky Connection Figure 10. Reducing the Switching-Node Rise Time ______________________________________________________________________________________ 21 MAX8732/MAX8733/MAX8734 protection circuit, this current-limit method is effective in almost every circumstance. A negative current limit prevents excessive reverse inductor currents when VOUT sinks 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 voltage-divider at ILIM_. The current-limit threshold adjustment range is from 50mV to 300mV. In the adjustable mode, the current-limit threshold voltage is precisely 1/10th the voltage at ILIM_. The threshold defaults to 100mV when ILIM_ is connected to VCC. MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers high-side MOSFETs at the expense of efficiency, without degrading the turn-off time (Figure 10). Adaptive dead-time circuits monitor the DL_ and DH_ drivers and prevent either FET from turning on until the other is fully off. This algorithm allows operation without shoot-through with a wide range of MOSFETs, minimizing delays and maintaining efficiency. There must be low-resistance, low-inductance paths from the gate drivers to the MOSFET gates for the adaptive dead-time circuit to work properly. Otherwise, the sense circuitry interprets the MOSFET gate as “off” when there is actually charge left on the gate. Use very short, wide traces measuring 10 to 20 squares (50mils to 100mils wide if the MOSFET is 1in from the device). POR, UVLO, and Internal Digital Soft-Start Power-on reset (POR) occurs when V+ rises above approximately 1V, resetting the undervoltage, overvoltage, and thermal-shutdown fault latches. LDO5 undervoltage-lockout (UVLO) circuitry inhibits switching when LDO5 is below 4V. DL_ is low if PRO is disabled; DL_ is high if PRO is enabled. The output voltages begin to ramp up once VCC exceeds its 4V UVLO and REF is in regulation. The internal digital soft-start timer begins to ramp up the maximum-allowed current limit during startup. The 1.7ms ramp occurs in five steps: 20%, 40%, 60%, 80%, and 100%. Power-Good Output (PGOOD) The PGOOD comparator continuously monitors both output voltages for undervoltage conditions. PGOOD is actively held low in shutdown, standby, and soft-start. PGOOD releases and digital soft-start terminates when BOTH outputs reach the error-comparator threshold. PGOOD goes low if EITHER output turns off or is 10% below its nominal regulation point. PGOOD is a true open-drain output. Note that PGOOD is independent of the state of PRO. Fault Protection The MAX8732/MAX8733/MAX8734 provide over/undervoltage fault protection. Drive PRO low to activate fault protection. Drive PRO high to disable fault protection. Once activated, the devices continuously monitor for both undervoltage and overvoltage conditions. Overvoltage Protection When the output voltage is 11% above the set voltage, the overvoltage fault protection activates. The synchronous rectifier turns on 100% and the high-side MOSFET turns off. This rapidly discharges the output capacitors, decreasing the output voltage. The output voltage may 22 dip below ground. For loads that cannot tolerate a negative voltage, place a power Schottky diode across the output to act as a reverse-polarity clamp. In practical applications, there is a fuse between the power source (battery) and the external high-side switches. If the overvoltage condition is caused by a short in the highside switch, turning the synchronous rectifier on 100% creates an electrical short between the battery and GND, blowing the fuse and disconnecting the battery from the output. Once an overvoltage fault condition is set, it can only be reset by toggling SHDN, ON_, or cycling V+ (POR). Undervoltage Protection When the output voltage is 30% below the set voltage for over 22ms (undervoltage shutdown blanking time), the undervoltage fault protection activates. Both SMPSs stop switching. The two outputs start to discharge (see the Discharge Mode (Soft-Stop) section). When the output voltage drops to 0.3V, the synchronous rectifiers turn on, clamping the outputs to GND. Toggle SHDN or ON_, or cycle V+ (POR) to clear the undervoltage fault latch. Thermal Protection The MAX8732/MAX8733/MAX8734 have thermal shutdown to protect the devices from overheating. Thermal shutdown occurs when the die temperature exceeds +160°C. All internal circuitry shuts down during thermal shutdown. The MAX8732/MAX8733/MAX8734 may trigger thermal shutdown if LDO_ is not bootstrapped from OUT_ while applying a high input voltage on V+ and drawing the maximum current (including short circuit) from LDO_. Even if LDO_ is bootstrapped from OUT_, overloading the LDO_ causes large power dissipation on the bootstrap switches, which may result in thermal shutdown. Cycling SHDN, ON3, ON5, or a V+ (POR) ends the thermal-shutdown state. Discharge Mode (Soft-Stop) When PRO is low and a transition to standby or shutdown mode occurs, or the output undervoltage fault latch is set, the outputs discharge to GND through an internal 12Ω switch, until the output voltages decrease to 0.3V. The reference remains active to provide an accurate threshold and to provide overvoltage protection. When both SMPS outputs discharge to 0.3V, the DL_ synchronous rectifier drivers are forced high. The synchronous rectifier drivers clamp the SMPS outputs to GND. When PRO is high, the SMPS outputs do not discharge and the DL_ synchronous rectifier drivers remain low. ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers MODE CONDITION COMMENT LDO5 < UVLO threshold Transitions to discharge mode after a V+ POR and after REF becomes valid. LDO5, LDO3, and REF remain active. DL_ is active if PRO is low. SHDN = high, ON3 or ON5 enabled Normal operation Overvoltage Protection Either output > 111% of nominal level, PRO = low DL_ is forced high. LDO3, LDO5 active. Exited by a V+ POR or by toggling SHDN, ON3, or ON5. Undervoltage Protection Either output < 70% of nominal after 22ms timeout expires and output is enabled, PRO = low If PRO is low, DL_ is forced high after discharge mode terminates. LDO3, LDO5 active. Exited by a V+ POR or by toggling SHDN, ON3, or ON5. PRO is low and either SMPS output is still high in either standby mode or shutdown mode Discharge switch (12Ω) connects OUT_ to PGND. One output may still run while the other is in discharge mode. Activates when LDO_ is in UVLO, or transition to UVLO, standby, or shutdown has begun. LDO3, LDO5 active. ON5, ON3 < startup threshold, SHDN = high DL_ stays high if PRO is low. LDO3, LDO5 active. Shutdown SHDN = low All circuitry off Thermal Shutdown TJ > +160°C All circuitry off. Exited by V+ POR or cycling SHDN, ON3, or ON5. Power-Up Run Discharge Standby Shutdown Mode Drive SHDN below the precise SHDN input falling-edge trip level to place the MAX8732/MAX8733/MAX8734 in their low-power shutdown state. The MAX8732/ MAX8733/MAX8734 consume only 6µA of quiescent current while in shutdown mode. When shutdown mode activates, the reference turns off, making the threshold to exit shutdown inaccurate. To guarantee startup, drive SHDN above 2V (SHDN input rising-edge trip level). For automatic shutdown and startup, connect SHDN to V+. If PRO is low, both SMPS outputs are discharged to 0.3V through a 12Ω switch before entering True Shutdown™. The accurate 1V falling-edge threshold on SHDN can be used to detect a specific analog voltage level and shut down the device. Once in shutdown, the 1.6V rising-edge threshold activates, providing sufficient hysteresis for most applications. For additional hysteresis, the undervoltage threshold can be made dependent on REF or LDO_, which go to 0V in shutdown. Power-Up Sequencing and On/Off Controls (ON3, ON5) 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. Connecting ON3 or ON5 to REF forces the respective outputs off while the other output is below regulation and Table 4. Power-Up Sequencing SHDN (V) VON3 (V) VON5 (V) LDO5 LDO3 5V SMPS 3V SMPS Low X X Off Off Off Off Off “> 2.4” => High Low Low On On (after REF powers up) Off “> 2.4” => High High High On On (after REF powers up) On On “> 2.4” => High High Low On On (after REF powers up) Off On “> 2.4” => High Low High On On (after REF powers up) On Off “> 2.4” => High High REF On On (after REF powers up) On (after 3V SMPS is up) On “> 2.4” => High REF High On On (after REF powers up) On On (after 5V SMPS is up) ______________________________________________________________________________________ True Shutdown is a trademark of Maxim Integrated Products, Inc. 23 MAX8732/MAX8733/MAX8734 Table 3. Operating-Mode Truth Table MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers 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 undervoltage lockout. Both supplies begin their power-down sequence immediately when the first supply turns off. Driving ON_ below 0.8V clears the overvoltage, undervoltage, and thermal fault latches. Adjustable-Output Feedback (Dual-Mode FB) Connect FB_ to GND to enable the fixed, preset SMPS output voltages (3.3V and 5V). Connect a resistive voltage-divider at FB_ between OUT_ and GND to adjust the respective output voltage between 2V and 5.5V (Figure 11). Choose R2 to be approximately 10kΩ, and solve for R1 using the equation: V OUT _ R1 = R2 × − 1 V FB where VFB = 2V nominal. When using the adjustable-output mode, set the 3.3V SMPS lower than the 5V SMPS. LDO5 connects to OUT5 through an internal switch only when OUT5 is above the LDO5 bootstrap-switch threshold (4.56V). LDO3 connects to OUT3 through an internal switch only when OUT3 is above the LDO3 bootstrap switch threshold (2.91V). Bootstrapping is most effective when the fixed output voltages are used. Once LDO_ is bootstrapped from OUT_, the internal linear regulator turns off. This V+ DH_ VOUT_ MAX8732 MAX8733 MAX8734 DL_ GND R1 OUT_ FB_ R2 Figure 11. Setting VOUT_ with a Resistor-Divider 24 reduces internal power dissipation and improves efficiency when LDO_ is powered with a high input voltage. Design Procedure Establish the input voltage range and maximum load current before choosing an inductor and its associated ripple-current ratio (LIR). The following four factors dictate the rest of the design: 1) Input Voltage Range. The maximum value (V+(MAX)) must accommodate the maximum AC adapter voltage. The minimum value (V+(MIN)) must account for the lowest input voltage after drops due to connectors, fuses, and battery selector switches. Lower input voltages result in better efficiency. 2) Maximum Load Current. The peak load current (ILOAD(MAX)) determines the instantaneous component stress 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 stress and 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 and MOSFET switching losses. The MAX8732 has a nominal switching frequency of 200kHz for the 5V SMPS and 300kHz for the 3.3V SMPS. The MAX8733 has a nominal switching frequency of 400kHz for the 5V SMPS and 500kHz for the 3.3V SMPS. The MAX8734 has a pin-selectable switching frequency. 4) Inductor Ripple Current Ratio (LIR). LIR is the ratio of the peak-peak ripple current to the average inductor current. Size and efficiency trade-offs must be considered when setting the inductor ripple current ratio. Low inductor values cause large ripple currents, resulting in the smallest size, but poor efficiency and high output noise. The minimum practical inductor value is one that causes the circuit to operate at 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 MAX8732/MAX8733/MAX8734s’ pulse-skipping algorithm (SKIP = GND) initiates skip mode at the critical conduction point, so the inductor’s operating point also determines the load current at which PWM/PFM switchover occurs. The optimum point is usually found between 20% and 50% ripple current. ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers L = ( VOUT _ V + − VOUT _ ) V + × f × LIR × ILOAD(MAX) Example: ILOAD(MAX) = 5A, V+ = 12V, VOUT5 = 5V, f = 200kHz, 35% ripple current or LIR = 0.35: ( 5V 12V − 5V L= ) 12V × 200kHz × 0.35 × 5A = 8.3µH Find a low-loss inductor having the lowest possible DC resistance that fits in the allotted dimensions. Ferrite cores are often the best choice. The core must be large enough not to saturate at the peak inductor current (IPEAK): IPEAK = ILOAD(MAX) + [(LIR/2) x ILOAD(MAX)] The inductor ripple current also impacts transientresponse performance, especially at low V+ - VOUT_ differences. Low inductor values allow the inductor current to slew faster, replenishing charge removed from the output filter capacitors by a sudden load step. The peak amplitude of the output transient (VSAG) is also a function of the maximum duty factor, which can be calculated from the on-time and minimum off-time: (∆ILOAD(MAX) ) VSAG = 2 V OUT _ × L K + t OFF(MIN) V+ V+− V OUT _ − t OFF(MIN) 2 × COUT × VOUT _ K V+ where minimum off-time = 0.350µs (max) and K is from Table 2. Determining 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 valley of the inductor current occurs at ILOAD(MAX) minus half of the ripple current; therefore: ILIMIT(LOW) > ILOAD(MAX) - [(LIR / 2) x ILOAD(MAX)] where ILIMIT(LOW) = minimum current-limit threshold voltage divided by the RDS(ON) of N2/N4 (MAX8734). For the MAX8732/MAX8733/MAX8734, the minimum current-limit threshold voltage is 93mV (ILIM_ = VCC). Use the worst-case maximum value for RDS(ON) from the MOSFET N2/N4 data sheet and add some margin for the rise in RDS(ON) with temperature. A good gener- al rule is to allow 0.5% additional resistance for each °C of temperature rise. Examining the 5A circuit example with a maximum RDS(ON) = 12mΩ at high temperature reveals the following: ILIMIT(LOW) = 93mV / 12mΩ > 5A - (0.35 / 2) 5A 7.75A > 4.125A 7.75A is greater than the valley current of 4.125A, so the circuit can easily deliver the full-rated 5A using the fixed 100mV nominal current-limit threshold voltage. Connect the source of the synchronous rectifier to a current-sense resistor to GND (MAX8732/MAX8733), and connect CS_ to that junction to set the current limit for the device. The MAX8732/MAX8733/MAX8734 limit the current with the sense resistor instead of the RDS(ON) of N2/N4. The maximum value of the sense resistor can be calculated with the equation: ILIM_ = 93mV / RSENSE 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 also be high enough to absorb the inductor energy while transitioning from full-load to no-load conditions without tripping the overvoltage fault latch. In applications where the output is subject to large 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: RESR ≤ VDIP ILOAD(MAX) where VDIP is the maximum-tolerable transient voltage drop. In non-CPU applications, the output capacitor’s size depends on how much ESR is needed to maintain an acceptable level of output voltage ripple: RESR ≤ VP−P LIR × ILOAD(MAX) where VP-P is the peak-to-peak output voltage ripple. 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 tantalum, OS-CON, and other electrolytic-type capacitors). ______________________________________________________________________________________ 25 MAX8732/MAX8733/MAX8734 Inductor Selection The switching frequency (on-time) and operating point (% ripple or LIR) determine the inductor value as follows: MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers When using low-capacity filter capacitors such as polymer types, capacitor size is usually determined by the capacity required to prevent VSAG and VSOAR from tripping the undervoltage and overvoltage fault latches during load transients in ultrasonic mode. For low input-to-output voltage differentials (VIN / VOUT < 2), additional output capacitance is required to maintain stability and good efficiency in ultrasonic mode. The amount of overshoot due to stored inductor energy can be calculated as: VSOAR = IPEAK 2 L 2COUT VOUT _ where IPEAK is the peak inductor current. Stability Considerations Stability is determined by the value of the ESR zero (fESR) relative to the switching frequency (f). The point of instability is given by the following equation: f fESR ≤ π where: fESR = 1 2π RESR COUT For a typical 300kHz application, the ESR zero frequency must be well below 95kHz, preferably below 50kHz. Low-ESR capacitors (especially polymer or tantalum), in widespread use at the time of publication, typically have ESR zero frequencies lower than 30kHz. In the design example used for inductor selection, the ESR needed to support a specified ripple voltage is found by the equation: ESR = VRIPPLE(P−P) LIR × ILOAD where LIR is the inductor ripple current ratio and ILOAD is the average DC load. Using LIR = 0.35 and an average load current of 5A, the ESR needed to support 50mVP-P ripple is 28mΩ. Do not place high-value ceramic capacitors directly across the fast-feedback inputs (OUT_ to GND for internal feedback, FB_ divider point for external feedback) without taking precautions to ensure stability. Large ceramic capacitors can have a high-ESR zero frequency and cause erratic, unstable operation. Adding a discrete resistor or placing the capacitors a couple of inches downstream from the junction of the inductor and OUT_ may improve stability. 26 Unstable operation manifests itself in two related but distinctly different ways: double pulsing and fast-feedback loop instability. Noise on the output or insufficient ESR may cause double pulsing. Insufficient ESR does not allow the amplitude of the voltage ramp in the output signal to be large enough. The error comparator mistakenly triggers a new cycle immediately after the 350ns minimum off-time period has expired. Double pulsing results in increased output ripple, and can indicate the presence of loop instability caused by insufficient ESR. Loop instability results in oscillations or ringing at the output after line or load perturbations, causing 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 (refer to the MAX8734 EV kit data sheet) and observe the output voltage-ripple envelope for overshoot and ringing. Monitoring the inductor current with an AC current probe may also provide some insight. Do not allow more than one cycle of ringing of under- or overshoot after the initial step response. Input Capacitor Selection The input capacitors must meet the input-ripple-current (IRMS) requirement imposed by the switching current. The MAX8732/MAX8733/MAX8734 dual switching regulators operate at different frequencies. This interleaves the current pulses drawn by the two switches and reduces the overlap time where they add together. The input RMS current is much smaller in comparison than with both SMPSs operating in phase. The input RMS current varies with load and the input voltage. The maximum input capacitor RMS current for a single SMPS is given by: VOUT _ V + − VOUT _ IRMS ≈ ILOAD V+ ( ) When V+ = 2 x VOUT_(D = 50%), IRMS has maximum current of ILOAD / 2. The ESR of the input-capacitor is important for determining capacitor power dissipation. All the power (IRMS2 x ESR) heats up the capacitor and reduces efficiency. Nontantalum chemistries (ceramic or OS-CON) are preferred due to their low ESR and resilience to power-up surge currents. Choose input capacitors that exhibit less than +10°C temperature rise at the RMS input current for optimal circuit longevity. Place the drains of the high-side switches close to each other to share common input bypass capacitors. ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers MOSFET Power Dissipation Worst-case conduction losses occur at the duty-factor extremes. For the high-side MOSFET, the worst-case power dissipation (PD) due to the MOSFET’s RDS(ON) occurs at the minimum battery voltage: V 2 OUT _ ILOAD RDS(ON) PD (NH Re sis tan ce) = VIN(MIN) ( ) following switching-loss calculation provides only a very rough estimate and is no substitute for bench evaluation, preferably including verification using a thermocouple mounted on NH (N1/N3): PD(NH Switching) = fSW ILOAD (VIN(MAX) )2 CRSSIGATE where CRSS is the reverse transfer capacitance of NH (N1/N3) and IGATE is the peak gate-drive source/sink current. For the synchronous rectifier, the worst-case power dissipation always occurs at maximum battery voltage: VOUT _ 2 PD (NL ) = 1− ILOAD RDS(ON) VIN(MAX) 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 and cause the fault latch to trip. To protect against this possibility, “overdesign” the circuit to tolerate: ILOAD = ILIMIT(HIGH) + (LIR / 2 ) x ILOAD(MAX) where I LIMIT(HIGH) is the maximum valley current allowed by the current-limit circuit, including threshold tolerance and resistance variation. Rectifier Selection Generally, a small high-side MOSFET reduces switching losses at high input voltage. However, the RDS(ON) required to stay within package power-dissipation limits often limits how small the MOSFET can be. The optimum situation occurs when the switching (AC) losses equal the conduction (RDS(ON)) losses. Switching losses in the high-side MOSFET can become an insidious heat problem when maximum battery voltage is applied, due to the squared term in the CV2 ✕ f switching-loss equation. Reconsider the high-side MOSFET chosen for adequate RDS(ON) at low battery voltages if it becomes extraordinarily hot when subjected to V+(MAX). Calculating the power dissipation in NH (N1/N3) due to switching losses is difficult since it must allow for quantifying 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 Current circulates from ground to the junction of both MOSFETs and the inductor when the high-side switch is off. As a consequence, the polarity of the switching node is negative with respect to ground. This voltage is approximately -0.7V (a diode drop) at both transition edges while both switches are off (dead time). The drop is IL x RDS(ON) when the low-side switch conducts. The rectifier is a clamp across the synchronous rectifier that catches the negative inductor swing during the dead time between turning the high-side MOSFET off and the synchronous rectifier on. The MOSFETs incorporate a high-speed silicon body diode as an adequate clamp diode if efficiency is not of primary importance. Place a Schottky diode in parallel with the body diode to reduce the forward voltage drop and prevent the N2/N4 MOSFET body diodes from turning on during the dead time. Typically, the external diode improves the efficiency by 1% to 2%. Use a Schottky diode with a DC current rating equal to 1/3 of the load current. For example, use an MBR0530 (500mA-rated) type for loads up to 1.5A, a ______________________________________________________________________________________ 27 MAX8732/MAX8733/MAX8734 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. Choose a high-side MOSFET (N1/N3) that has conduction losses equal to the switching losses at the typical battery voltage for maximum efficiency. Ensure that the conduction losses at the minimum input voltage do not exceed the package thermal limits or violate the overall thermal budget. 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 synchronous rectifier (N2/N4) with the lowest possible RDS(ON). Ensure the gate is not pulled up by the high-side switch turning on due to parasitic drain-to-gate capacitance, causing cross-conduction problems. Switching losses are not an issue for the synchronous rectifier in the buck topology since it is a zero-voltage switched device when using the buck topology. MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers 1N5819 type for loads up to 3A, or a 1N5822 type for loads up to 10A. The rectifier’s rated reverse breakdown voltage must be at least equal to the maximum input voltage, preferably with a 20% derating factor. Boost Supply Diode A signal diode, such as a 1N4148, works well in most applications. Use a small (20mA) Schottky diode for slightly improved efficiency and dropout characteristics, if the input voltage can go below 6V. Do not use large power diodes, such as 1N5817 or 1N4001, since high-junction capacitance can force LDO5 to excessive voltages. Applications Information Time One-Shot section), tOFF(MIN) is from the EC table, and K is taken from Table 2. The absolute minimum input voltage is calculated with h = 1. Operating frequency must be reduced or h must be increased and output capacitance added to obtain an acceptable VSAG if calculated V+(MIN) is greater than the required minimum input voltage. Calculate VSAG to be sure of adequate transient response if operation near dropout is anticipated. Dropout Design Example MAX8733: With VOUT5 = 5V, fsw = 400kHz, K = 2.25µs, tOFF(MIN) = 350ns, VDROP1 = VDROP2 = 100mV, and h = 1.5, the minimum V+ is: Dropout Performance The output voltage-adjust range for continuous-conduction operation is restricted by the nonadjustable 350ns (max) minimum off-time one-shot. Use the slower 5V SMPS for the higher of the two output voltages for best dropout performance in adjustable feedback mode. The duty-factor limit must be calculated using worst-case values for on- and off-times, when working with low input voltages. Manufacturing tolerances and internal propagation delays introduce an error to the tON K-factor. 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 VSAG equation in the Output Capacitor Selection section). The absolute point of dropout occurs 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 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 tradeoffs between V SAG , output capacitance, and minimum operating voltage. For a given value of h, the minimum operating voltage can be calculated as: V + (MIN) = (VOUT _ + VDROP1) t OFF (MIN) × h 1− K + VDROP2 − VDROP1 where VDROP1 and VDROP2 are the parasitic voltage drops in the discharge and charge paths (see the On28 V + (MIN) = (5V + 0.1V) 0.35µs × 1.5 1− 2.25µs + 0.1V − 0.1V = 6.65V Calculating with h = 1 yields: V + (MIN) = (5V + 0.1V) 0.35µs × 1 1− 2.25µs + 0.1V − 0.1V = 6.04 V Therefore, V+ must be greater than 6.65V. A practical input voltage with reasonable output capacitance would be 7.5V. MAX1658/ MAX1659 V+ LDO DH_ MAX8732 MAX8733 MAX8734 DL_ T1 10µH 1:2.2 12V POSITIVE SECONDARY OUTPUT 5V MAIN OUTPUT T1 = TRANSPOWER TECHNOLOGIES TTI-5870 Figure 12. Transformer-Coupled Secondary Output ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers A coupled inductor or transformer can be substituted for the inductor in the 5V or 3.3V SMPS to create an auxiliary output (Figure 12). The MAX8732/MAX8733/MAX8734 are particularly well suited for such applications because they can be configured in ultrasonic or forced-PWM mode to ensure good load regulation when the main supplies are lightly loaded. An additional postregulation circuit can be used to improve load regulation and limit output current. 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 MAX8732/MAX8733/MAX8734 must also be adjusted accordingly. Extremes of low input-output differentials, 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 Determining the Current Limit section): I TOTAL = PTOTAL / VOUT 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: LPRIMARY = N= VOUT (VIN(MAX) − VOUT VIN(MAX) × ƒ × I TOTAL × LIR VSEC + VFWD VOUT(MIN) + VRECT 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, VOUT(MIN) is the minimum value of the main output voltage, and VRECT is the onstate 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 V OUT from the secondary voltage (V SEC – VOUT) in the transformer turns-ratio equation above. The secondary diode in coupled-inductor applications must withstand flyback voltages greater than 60V, which usually rules out most Schottky rectifiers. Common silicon rectifiers, such as the 1N4001, are also prohibited because they are too slow. This often makes fast silicon rectifiers such as the MURS120 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 - VOUT) ✕ N where N is the transformer turns ratio (secondary windings/primary windings), VSEC is the maximum secondary DC output voltage, and VOUT is the primary (main) output voltage. If the secondary winding is returned to VOUT instead of ground, subtract VOUT from VFLYBACK 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. The optional linear postregulator must be selected to deliver the required load current from the transformer’s rectified DC output. The linear regulator should be configured to run close to dropout to minimize power dissipation and should have good output accuracy under those conditions. Input and output capacitors are chosen to meet line regulation, stability, and transient requirements. There are a wide variety of linear regulators appropriate for this application; consult the specific linear-regulator data sheet for details. Widely different output loads affect load regulation. In particular, when the secondary output is left unloaded while the main output is fully loaded, the secondary output capacitor may become overcharged by the leakage inductance, reaching voltages much higher than intended. In this case, a minimum load or overvoltage protection may be required on the secondary output to protect any device connected to this output. PC Board Layout Guidelines Careful PC board layout is critical to achieve minimal switching losses and clean, stable operation. This is especially true when multiple converters are on the same PC board where one circuit can affect the other. The switching power stages require particular attention (Figure 13). Refer to the MAX1999 Evaluation Kit data sheet for a specific layout example. Mount all of the power components on the top side of the board with their ground terminals flush against one another, if possible. Follow these guidelines for good PC board layout: • Isolate the power components on the top side from the sensitive analog components on the bottom side with a ground shield. Use a separate PGND plane under the OUT3 and OUT5 sides (called PGND3 and ______________________________________________________________________________________ 29 MAX8732/MAX8733/MAX8734 Use of Coupled Inductors to Create Auxiliary Outputs USE PGND PLANE TO: USE AGND PLANE TO: - BYPASS LDO_ - BYPASS VCC AND REF - TERMINATE EXTERNAL FB - CONNECT PGND TO THE TOPSIDE STAR GROUND DIVIDER (IF USED) OUT5 VIA BETWEEN POWER - TERMINATE RILIM AND ANALOG GROUND (IF USED) AGND VIA TO OUT5 - PIN-STRAP CONTROL INPUTS PGND L1 VIA TO LX5 CONNECT PGND TO AGND BENEATH THE CONTROLLER AT ONE POINT ONLY AS SHOWN. C3 C4 VIA TO OUT3 C1 N4 C2 N3 VIAS TO GROUND OUT3 N2 D2 ANALOG GROUND PLANE ON INNER LAYER VIA TO PGND GROUND D1 MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers L2 N1 V+ VIA TO LX3 NOTE: EXAMPLE SHOWN IS FOR DUAL N-CHANNEL MOSFET. Figure 13. PC Board Layout Example PGND5). Avoid the introduction of AC currents into the PGND3 and PGND5 ground planes. Run the power plane ground currents on the top side only, if possible. • Use a star ground connection on the power plane to minimize the crosstalk between OUT3 and OUT5. • 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 must be approached in terms of fractions of centimeters, where a single milliohm of excess trace resistance causes a measurable efficiency penalty. • CS_ (MAX8732/MAX8733)/LX_ (MAX8734) and GND connections to the synchronous rectifiers for current limiting must be made using Kelvin-sense connections to guarantee the current-limit accuracy. With 8pin SO MOSFETs, this is best done by routing power to the MOSFETs from outside using the top copper layer, while connecting CS_/LX_ traces inside (underneath) the MOSFETs. • 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 30 allow distance between the inductor and the synchronous rectifier or between the inductor and the output filter capacitor. • Ensure that the OUT_ connection to COUT_ is short and direct. However, in some cases it may be desirable to deliberately introduce some trace length between the OUT_ connector node and the output filter capacitor (see the Stability Considerations section). • Route high-speed switching nodes (BST_, DH_, LX_, and DL_) away from sensitive analog areas (REF, ILIM_, and FB_). Use PGND3 and PGND5 as an EMI shield to keep radiated switching noise away from the IC’s feedback divider and analog bypass capacitors. • Make all pin-strap control input connections (SKIP, ILIM_, etc.) to GND or VCC of the device. Layout Procedure 1) Place the power components first with ground terminals adjacent (N2/N4 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 the synchronousrectifier MOSFETs, preferably on the back side in order to keep DH_, GND, and the DL_ gate drive lines short and wide. The DL_ gate trace must be short and wide, measuring 50mils to 100mils wide if the MOSFET is 1in from the controller device. 3) Group the gate-drive components (BST_ diode and capacitor, V+ bypass capacitor) together near the controller device. ______________________________________________________________________________________ High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers 5) On the board’s top side (power planes), make a star ground to minimize crosstalk between the two sides. The top-side star ground is a star connection of the input capacitors and synchronous rectifiers. Keep the resistance low between the star ground and the source of the synchronous rectifiers for accurate current limit. Connect the top-side star ground (used for MOSFET, input, and output capacitors) to the small island with a single short, wide connection (preferably just a via). Create PGND islands on the layer just below the top-side layer (refer to the MAX1999 EV kit for an example) to act as an EMI shield if multiple layers are available (highly recommended). Connect each of these individually to the star ground via, which connects the top side to the PGND plane. Add one more solid ground plane under the device to act as an additional shield, and also connect the solid ground plane to the star ground via. Pin Configurations (continued) TOP VIEW CS3 1 28 BST3 PGOOD 2 27 LX3 ON3 3 26 DH3 ON5 4 25 LDO3 ILIM3 5 SHDN 6 24 DL3 MAX8732 MAX8733 23 GND FB3 7 22 OUT3 REF 8 21 OUT5 FB5 9 20 V+ PRO 10 19 DL5 ILIM5 11 18 LDO5 SKIP 12 17 VCC CS5 13 16 DH5 BST5 14 15 LX5 QSOP Chip Information TRANSISTOR COUNT: 8335 PROCESS: BiCMOS 6) Connect the output power planes (VCORE and system ground planes) directly to the output filter capacitor positive and negative terminals with multiple vias. ______________________________________________________________________________________ 31 MAX8732/MAX8733/MAX8734 4) Make the DC-DC controller ground connections as follows: near the device, create a small analog ground plane. Connect the small analog ground plane to GND (Figure 13) and use the plane for the ground connection for the REF and VCC bypass capacitors, FB dividers, and ILIM resistors (if any). Create another small ground island for PGND, and use the plane for the V+ bypass capacitor, placed very close to the device. Connect the AGND and PGND planes together at the GND pin of the device. 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.) QSOP.EPS MAX8732/MAX8733/MAX8734 High-Efficiency, Quad-Output, Main PowerSupply Controllers for Notebook Computers PACKAGE OUTLINE, QSOP .150", .025" LEAD PITCH 21-0055 E 1 1 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. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 32 © 2004 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products.