DATASHEET SIGNS R NEW DE O F D E D N PART MME ACEMENT NOT RECO L P E R D E ND RECOMME ISL97645A EL7520, EL7520A 4-Channel DC/DC Controller FN7318 Rev 0.00 July 12, 2005 EL7520 and EL7520A are 4-channel DC/DC controllers that provide a complete power supply system for TFT-LCD applications. They consist of a 1MHz PWM boost controller, which generates the main voltage for the column driver, and three LDO controllers for VON, VOFF, and VLOGIC supplies. They also include integrated start-up sequence and start-up delay control. Features EL7520 and EL7520A operate from 3V to 5.5V. The boost controller can drive a wide range of output current depending on the external FET. It can be programmed to operate in either P-mode for fast transient response or PImode for improved load regulation. The EL7520 and EL7520A also integrate fault protection for all four output channels. When a fault is detected, the device is latched off until either the input supply voltage or enable is cycled. Therefore, they are ideal to use in any size of TFT-LCD panels. • Integrated start-up sequence for VLOGIC/VBOOST, VOFF, VON or VLOGIC, VOFF, VBOOST, VON The EL7520 and EL7520A are available in a 20 Ld 4x4 QFN package with maximum height of 0.9mm and is specified for operation of the -40°C to +85°C temperature range. • 3V to 5.5V VDD • Complete TFT-LCD supply controller - 1MHz PWM boost controller - VON LDO controller - VOFF LDO controller - Logic supply LDO controller - VLOGIC permanently enabled in 'A version (EL7520A) • Programmable sequence delay • In-rush current control • Fully fault protected • Thermal shutdown • Internal soft-start • 20 Ld 4x4 QFN package • Low cost Ordering Information • Pb-Free plus anneal available (RoHS compliant) PACKAGE (Pb-FREE) TAPE & REEL PKG. DWG. # EL7520ILZ 20 Ld 4x4 QFN - MDP0046 • LCD monitors (15”+) EL7520ILZ-T7 20 Ld 4x4 QFN 7” MDP0046 • LCD-TV (up to 40”+) EL7520ILZ-T13 20 Ld 4x4 QFN 13” MDP0046 • Notebook displays (up to 16”) EL7520AILZ 20 Ld 4x4 QFN - MDP0046 • Industrial/medical LCD displays EL7520AILZ-T7 20 Ld 4x4 QFN 7” MDP0046 EL7520AILZ-T13 20 Ld 4x4 QFN 13” MDP0046 Pinout 16 DRVP 17 EN 18 VDD EL7520 AND EL7520A (20 LD 4X4 QFN) TOP VIEW 19 VDDP NOTE: Intersil Pb-free plus anneal products employ special Pb-free material sets; molding compounds/die attach materials and 100% matte tin plate termination finish, which are RoHS compliant and compatible with both SnPb and Pb-free soldering operations. Intersil Pb-free products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020. Applications 20 PG PART NUMBER (NOTE) CDLY 1 15 FBP DRVB 2 14 DRVL THERMAL PAD PGND 3 13 FBL 12 DRVN ISAD 4 ISIN 5 FN7318 Rev 0.00 July 12, 2005 VREF 10 CINT 9 FBB 8 SGND 7 DELB 6 11 FBN Page 1 of 18 EL7520, EL7520A Absolute Maximum Ratings (TA = 25°C) Thermal Information VDELB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25V VDRVP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .36V VDRVN . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -20V VDDP, VDD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.5V Thermal Resistance (Typical, Notes 1, 2) JA (°C/W) JC (°C/W) QFN Package. . . . . . . . . . . . . . . . . . . . 40 7.5 VDRVL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.5V Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . .-65°C to +150°C Ambient Operating Temperature . . . . . . . . . . . . . . . .-40°C to +85°C Maximum Continuous Junction Temperature . . . . . . . . . . . . . 125°C CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. NOTES: 1. JA is measured in free air with the component mounted on a high effective thermal conductivity test board with “direct attach” features. See Tech Brief TB379. 2. For JC, the “case temp” location is the center of the exposed metal pad on the package underside. IMPORTANT NOTE: All parameters having Min/Max specifications are guaranteed. Typ values are for information purposes only. Unless otherwise noted, all tests are at the specified temperature and are pulsed tests, therefore: TJ = TC = TA Electrical Specifications VDD = 5V, VBOOST = 11V, ILOAD = 40mA, VON = 15V, VOFF = -5V, VLOGIC = 2.5V, over temperature from 40°C to 85°C, unless otherwise specified. PARAMETER DESCRIPTION CONDITION MIN TYP MAX UNIT 5.5 V 1.6 2.5 mA 5 30 µA 640 800 µA 900 1000 1100 kHz 1.19 1.215 1.235 V 1.187 1.215 1.238 V SUPPLY VS Supply Voltage IS Quiescent Current 3 Enabled, LX not switching Disabled, EL7520 Disabled, EL7520A FOSC Oscillator Frequency BOOST VREF Reference Voltage CREF VREF Capacitor VFBB Feedback Reference Voltage VF_FBB FBB Fault Trip Point DMAX Maximum Duty Cycle TA = 25°C 100 TA = 25°C 1.192 1.205 1.218 V 1.188 1.205 1.222 V VFBB falling 1 % Test with 24m RDS(ON) MOSFET, ILOAD = 400mA 90 Feedback Input Bias Current PI mode, VFBB = 1.35V 50 VBOOST/ VIN Line Regulation CINT = 2.2nF, IOUT = 200mA VIN = 3V to 5.5V VBOOST/ IBOOST Load Regulation - “P” Mode CINT pin strapped to VDD VBOOST/ IBOOST Load Regulation - “PI” Mode IOUT = 10mA to 200mA I(VREF) VCINT_T V 85 Boost Efficiency Eff nF CINT Pl Mode Select Threshold % 500 nA 0.05 %/V 3 % 0.1 % 4.7 4.8 V VON LDO FBP Regulation Voltage IDRVP = 0.2mA, TA = 25°C 1.181 1.211 1.229 V IDRVP = 0.2mA 1.177 1.211 1.233 V FBP Fault Trip Point VFBP falling 0.95 1 1.05 V IFBP FBP Input Bias Current VFBP = 1.35V -250 250 nA GMP FBP Effective Transconductance VDRVP = 25V, IDRVP = 0.2 to 2mA VFBP VF_FBP FN7318 Rev 0.00 July 12, 2005 50 mS Page 2 of 18 EL7520, EL7520A Electrical Specifications VDD = 5V, VBOOST = 11V, ILOAD = 40mA, VON = 15V, VOFF = -5V, VLOGIC = 2.5V, over temperature from 40°C to 85°C, unless otherwise specified. (Continued) PARAMETER VON/I(VON) IDRVP IL_DRVP DESCRIPTION VON Load Regulation CONDITION MIN I(VON) = 0mA to 20mA DRVP Sink Current VFBP = 1.1V, VDRVP = 25V DRVP Leakage Current VFBL = 1.5V, VDRVL = 35V FBN Regulation Voltage IDRVN = 0.2mA, TA = 25°C TYP MAX -0.5 2 UNIT % 4 mA 0.1 5 µA 0.173 0.203 0.233 V VOFF LDO VFBN IDRVN = 0.2mA 0.171 0.203 0.235 V FBN Fault Trip Point VFBN falling 0.38 0.4 0.48 V IFBN FBN Input Bias Current VFBN = 1.25V -250 250 nA GMN FBN Effective Transconductance VDRVN = -6V, IDRVN = 0.2mA to 2mA VOFF/ I(VOFF) VOFF Load Regulation I(VOFF) = 0mA to 20mA IDRVN DRVN Source Current VFBN = 0.3V, VDRVN = -6V DRVN Leakage Current VFBN = 0V, VDRVN = -20V FBL Regulation Voltage IDRVL = 1mA, TA = 25°C IDRVL = 1mA VF_FBN IL_DRVN 2 50 mS -0.15 % 4 mA 0.1 5 µA 1.176 1.2 1.224 V 1.174 1.2 1.226 V 1 1.05 V 500 nA VLOGIC LDO VFBL FBL Fault Trip Point VFBL falling 0.90 IFBL FBL Input Bias Current VFBL = 1.25V -500 GML FBL Effective Transconductance VDRVL = 2.5V, IDRVP = 1mA to 8mA 200 mS VLOGIC Load Regulation I(VLOGIC) = 0mA to 500mA -0.5 % DRVL Sink Current VFBL = 1.1V, VDRVL = 2.5V 16 mA DRVL Leakage Current VFBL = 1.5V, VDRVL = 5.5V 0.1 tON Turn On Delay CDLY = 0.1µF 30 ms tSS Soft-start Time CDLY = 0.1µF 2 ms tDEL1 Delay Between AVDD and VOFF CDLY = 0.1µF 10 ms tDEL2 Delay Between VON and VOFF CDLY = 0.1µF 17 ms tDEL3 Delay Between VOFF and Delayed VBOOST CDLY = 0.1µF 10 ms IDELB DELB Pull-down Current VDELB > 0.6V 50 µA VDELB < 0.6V 1.4 mA 100 nF VF_FBL VLOGIC/ I(VLOGIC) IDRVL IL_DRVL 5 5 µA SEQUENCING CDEL Delay Capacitor FAULT DETECTION TFAULT Fault Time Out OT Over-temperature Threshold IPG PG Pull-down Current CDLY = 0.1µF 50 ms 140 °C VPG > 0.6V 15 µA VPG < 0.6V 1.7 mA LOGIC VHI Logic High Threshold VLO Logic Low Threshold ILOW Logic Low bias Current -1 IHIGH Logic High bias Current 12 FN7318 Rev 0.00 July 12, 2005 2.2 V 0.8 V 0.1 1 µA 18 24 µA Page 3 of 18 EL7520, EL7520A Typical Performance Curves 100 100 VIN = 5V EFFICIENCY (%) 90 VIN = 3V 80 70 60 0 500 1000 IOUT (mA) 0 LINE REGULATION (%) -0.005 -0.5 -0.01 -1 -0.015 -1.5 -0.02 -2 -0.025 4 200 400 5 1000 1200 VIN = 3V -0.1 VIN = 5V -0.15 -0.2 -0.25 -0.3 -0.4 6 0 500 1000 1500 IOUT (mA) FIGURE 4. VBOOST LOAD REGULATION (PI MODE) FIGURE 3. VBOOST LINE REGULATION 0 -1 LOAD REGULATION (%) 0 LOAD REGULATION (%) 800 -0.05 VIN (V) VIN = 3V -2 VIN = 5V -3 -4 -5 -6 600 -0.35 -0.03 3 0 0 PI MODE -2.5 2 70 FIGURE 2. VBOOST EFFICIENCY vs IOUT (P MODE) 0 P MODE 1 VIN = 3V 80 IOUT (mA) FIGURE 1. VBOOST EFFICIENCY vs IOUT (PI MODE) 0 90 60 1500 LOAD REGULATION (%) EFFICIENCY (%) VIN = 5V -0.1 -0.2 -0.3 -0.4 -0.5 -0.6 0 200 400 600 800 1000 1200 IOUT (mA) FIGURE 5. VBOOST LOAD REGULATION (P MODE) FN7318 Rev 0.00 July 12, 2005 0 20 40 60 80 IOUT (mA) FIGURE 6. VON LOAD REGULATION Page 4 of 18 EL7520, EL7520A EL7520, EL7520A (Continued) 0 0 -0.2 -0.2 LOAD REGULATION (%) LOAD REGULATION (%) Typical Performance Curves -0.4 -0.6 -0.8 -1 -1.2 -1.4 -0.4 -0.6 -0.8 -1 -1.2 0 20 40 60 80 100 0 FIGURE 7. VOFF LOAD REGULATION 200 300 400 500 600 700 FIGURE 8. VLOGIC LOAD REGULATION VCDLY VCDLY EN VBOOST VLOGIC VLOGIC CDLY=0.1µF VREF FIGURE 9. EL7520 START-UP SEQUENCE CDLY=0.1µF VREF TIME (20ms/DIV) TIME (20ms/DIV) FIGURE 10. EL7520 START-UP SEQUENCE VBOOST-DELAY VBOOST VLOGIC VLOGIC VOFF VOFF CDLY=0.1µF VON TIME (10ms/DIV) FIGURE 11. EL7520 START-UP SEQUENCE FN7318 Rev 0.00 July 12, 2005 100 IOUT (mA) IOUT (mA) CDLY=0.1µF VON TIME (20ms/DIV) FIGURE 12. EL7520 START-UP SEQUENCE Page 5 of 18 EL7520, EL7520A Typical Performance Curves (Continued) VCDLY VCDLY VBOOST EN VLOGIC VLOGIC VREF VREF CDLY=0.1µF CDLY=0.1µF TIME (20ms/DIV) TIME (20ms/DIV) FIGURE 13. EL7520A START-UP SEQUENCE FIGURE 14. EL7520A START-UP SEQUENCE VBOOST VBOOST-DELAY VLOGIC VLOGIC VOFF VOFF VON VON CDLY=0.1µF CDLY=0.1µF TIME (20ms/DIV) TIME (20ms/DIV) FIGURE 16. EL7520A START-UP SEQUENCE FIGURE 15. EL7520A START-UP SEQUENCE 0.5µs/DIV FIGURE 17. LX WAVEFORM-DISCONTINUOUS MODE FN7318 Rev 0.00 July 12, 2005 Page 6 of 18 EL7520, EL7520A Typical Performance Curves (Continued) 0.5µs/DIV FIGURE 18. LX WAVEFORM-CONTINUOUS MODE CH1=VBOOST, 100mV/DIV CH4=LOAD CURRENT, 200mA/DIV 0.2ms/DIV FIGURE 20. VBOOST TRANSIENT RESPONSE CH1=VON, 100mV/DIV CH4=LOAD CURRENT, 50mA/DIV 50µs/DIV FIGURE 22. VON TRANSIENT RESPONSE FN7318 Rev 0.00 July 12, 2005 20mV/DIV FIGURE 19. VBOOST OUTPUT VOLTAGE RIPPLE CH1=VLOGIC, 20mV/DIV CH4=LOAD CURRENT, 100mA/DIV 50µs/DIV FIGURE 21. VLOGIC TRANSIENT RESPONSE CH1=VOFF, 50mV/DIV CH4=LOAD CURRENT, 50mA/DIV 50µs/DIV FIGURE 23. VOFF TRANSIENT RESPONSE Page 7 of 18 EL7520, EL7520A Pin Descriptions PIN NUMBER PIN NAME FUNCTION DESCRIPTION 1 CDLY With a capacitor connected from this pin to GND sets the delay time for start-up sequence and sets the fault timeout time 2 DRVB Gate driver output for the external N channel switch; the pulse voltage follows the input voltage 3 PGND Power GND 4 ISAD With a resistor connected from this pin to GND sets the current limit of the external N channel FET 5 ISIN Sense the drain voltage of the external N channel FET and connected to the internal current limit comparator 6 DELB Active low control output for optional delay control for external VBOOST P channel FET; when fault is detected, this pin goes to high 7 SGND Low noise signal ground 8 FBB Boost regulator voltage feedback input pin; regulates to 1.2V nominal 9 CINT VBOOST integrator output, connect 2.2nF to analog GND for PI mode or connect to VREF for P mode operation 10 VREF Bandgap voltage bypass terminal; bypass with a 0.1µF to analog GND; can be used as charge pump reference 11 FBN 12 DRVN 13 FBL 14 DRVL Logic LDO base drive; open drain of an internal N channel MOSFET 15 FBP Positive LDO voltage feedback input pin; regulates to 1.2V nominal 16 DRVP 17 EN 18 VDD 19 VDDP 20 PG FN7318 Rev 0.00 July 12, 2005 Negative LDO voltage feedback input pin; regulates to 0.2V nominal Negative LDO base drive; open drain of an internal P channel MOSFET Logic LDO voltage feedback input pin; regulates to 1.2V nominal Positive LDO base drive; open drain of an internal N channel MOSFET Enable pin for the chip; high enable; low disabled Positive supply for all internal circuitry except DRVB Positive supply for external N channel FET gate drive (DRVB) Output gate drive of the external fault protection P channel FET; when chip is disabled or when a fault has been detected, this pin is high Page 8 of 18 EL7520, EL7520A Typical Application LX NODE 1 Q1 VIN L1 6.8µH 1000pF C1 C0 R0 500k C3 10µF D1 10µFx2 C7 R13 7K EN 10K C41 0.1µF 0.1µF R12 FBP VREF VREF Q11 DRVP 20K C22 230K R11 DRVL C31 21.7K R41 10µF D12 C24 C15 1µF C12 0.1µF D11 20V VON 0.1µF LX Q21 DRVN R42 2.5V C14 0.1µF 3K 500 VLGC R16 20K R23 R43 Q31 C11 0.1µF C13 0.1µF C23 2.2nF VDD 4.7µF NODE 1 LX 200K CINT R7 0.1µF R8 10K R20 ISAD R6 10 C6 0.01µF FBB CDELAY DELB 0.1µF C9 R1 7.5K DRVB C10 0.1µF C16 C2 1M 10µF R2 ISIN VDDP R9 62.5K Q2 PG 12V VBOOST Q3 FBN FBL 20K 20K SGND C25 0.1µF R22 PGND 104K R21 D21 -8V VOFF C20 4.7µF VREF Applications Information TABLE 1. RECOMMENDED COMPONENTS (Continued) The EL7520 and EL7520A provide a multiple output power supply solution for TFT-LCD applications. The system consists of a high efficiency boost controller and three low cost linear-regulator controllers (VON, VOFF, and VLOGIC). DESIGNATION Q1 -2.4 -20V P-channel 1.8V specified PowerTrench MOSFET (SuperSOT-3) Fairchild FDN304P The block diagram of the whole part is shown in Figure 24. Table 1 lists the recommended components. Q2 6.3A 30V single N-channel logic level PowerTrench MOSFET (SOT-23) Fairchild FDC655AN Q3 -2A –30V single P-channel logic level PowerTrench MOSFET (SuperSOT-3) Fairchild FDN360P TABLE 1. RECOMMENDED COMPONENTS DESIGNATION DESCRIPTION DESCRIPTION C1, C2, C3, C31 10µF, 16V, X7R ceramic capacitor (1206) TDK C3216X7R1C106M Q11 200mA 40V PNP amplifier (SOT-23) Fairchild MMBT3906 C20 4.7µF, 16V X5R ceramic capacitor (1206) TDK C3216X5R1A475K Q21 200mA 40V NPN amplifier (SOT-23) Fairchild MMBT3904 C15 1µF, 25V X7R ceramic capacitor (1206) TDK C3216X7R1E105K Q31 1A 30V PNP low saturation amplifier (SOT-23) Fairchild FMMT549 D1 1A 20V low leakage schottky rectifier (CASE 457-04) ON SEMI MBRM120ET3 D11, D12, D21 200mA 30V schottky barrier diode (SOT-23) Fairchild BAT54S L1 6.8mH 1.3A inductor TDK SLF6025T-6R8M1R3-PF FN7318 Rev 0.00 July 12, 2005 Page 9 of 18 EL7520, EL7520A VREF REFERENCE GENERATOR OSCILLATOR SLOPE COMPENSATION LX OSC PWM LOGIC CONTROLLER DRVB BUFFER VOLTAGE AMPLIFIER FBB GM AMPLIFIER ISIN CINT CURRENT AMPLIFIER UVLO COMPARATOR CURRENT LIMIT COMPARATOR SHUTDOWN & STARTUP CONTROL EN VREF CURRENT LIMIT REF GENERATOR ISAD SS + DRVP BUFFER THERMAL SHUTDOWN FBP UVLO COMPARATOR SS + DRVN - SS 0.2V VREF + DRVL - BUFFER BUFFER FBN 0.4V FBL UVLO COMPARATOR UVLO COMPARATOR FIGURE 24. BLOCK DIAGRAM Boost Converter The main boost converter is a current mode PWM controller operating at a fixed frequency. The 1MHz switching frequency enables the use of low profile inductor and multilayer ceramic capacitors, which results in a compact, low-cost power system for LCD panel design. The boost converter can operate in continuous or discontinuous inductor current mode. The EL7520 and EL7520A are designed for continuous current mode, but they can also operate in discontinuous current mode at light load. In continuous current mode, current flows continuously in the inductor during the entire switching cycle in steady state operation. The voltage conversion ratio in continuous current mode is given by: V BOOST 1 ------------------------ = ------------1–D V IN Figure 25 shows the function diagram of the boost controller. It uses a summing amplifier architecture consisting of GM stages for voltage feedback, current feedback and slope compensation. A comparator looks at the peak inductor current cycle by cycle and terminates the PWM cycle if the current limit is reached. An external resistor divider is required to divide the output voltage down to the nominal reference voltage. Current drawn by the resistor network should be limited to maintain the overall converter efficiency. The maximum value of the resistor network is limited by the feedback input bias current and the potential for noise being coupled into the feedback pin. A resistor network in the order of 60k is recommended. The boost converter output voltage is determined by the following equation: R1 + R2 V BOOST = --------------------- V REF R1 Where D is the duty cycle of switching MOSFET. FN7318 Rev 0.00 July 12, 2005 Page 10 of 18 EL7520, EL7520A VREF VIN REFERENCE GENERATOR OSCILLATOR SLOPE COMPENSATION OSC VBOOST PWM LOGIC CONTROLLER DRVB BUFFER VOLTAGE AMPLIFIER GM AMPLIFIER ISIN CURRENT AMPLIFIER SHUTDOWN & STARTUP CONTROL UVLO COMPARATOR CURRENT LIMIT REF GENERATOR ISAD CURRENT LIMIT COMPARATOR FIGURE 25. FUNCTION DIAGRAM OF THE BOOST CONTROLLER The internal current limit circuitry is shown in Figure 26. The circuit senses the voltage across the RDS(ON) when the MOSFET is on; then compare it to the internal voltage reference to realize the current limit. The internal voltage reference is generated by a 10µA current and any additional current set at ISAD pin flowing through an 8k resistor. The voltage reference is based on the following equation: VDD 10µA + VREF V ISAD V THRESHOLD = ----------------- + 10A 8K R1 Where VISAD is the voltage at pin ISAD. LX ISIN ISAD 1K 8K LOGIC CONTROLLER DRVB R1 V ISAD = V REF – V BE – 1K I SAD FIGURE 26. CURRENT LIMIT BLOCK DIAGRAM V ISAD I SAD = ----------------R1 Where VBE 0.7V The external resistor R1 should be chosen in the order of 100K to generate µA of current. Hence the maximum output current is determined by the following equation: V IN V THRESHOLD I L I OMAX = --------------------------------------- – -------- --------R DSON 2 VO Where IL is the peak to peak inductor ripple current, and is set by: V IN D I L = --------- ----L fS fS is the switching frequency; D is the duty cycle. V O – V IN D = -----------------------VO FN7318 Rev 0.00 July 12, 2005 Page 11 of 18 EL7520, EL7520A Input Capacitor The input capacitor is used to supply the current to the converter. It is recommended that CIN be larger than 10µF. The reflected ripple voltage will be smaller with larger CIN. The voltage rating of input capacitor should be larger than maximum input voltage. Boost Inductor A 3.3µH inductor is recommended due to the fixed internal slope compensation. The inductor must be able to handle the following average and peak current: Compensation The EL7520 and EL7520A can operate in either P mode or PI mode. Connecting CINT pin directly to VIN will enable P mode. For better load regulation, use PI mode with a 2.2nF capacitor between CINT and ground. Linear-Regulator Controllers (VON, VLOGIC, and VOFF) IO I LAVG = ------------1–D I L I LPK = I LAVG + -------2 Switching MOSFET Due to the parasitic inductance of the trace, the MOSFET will experience spikes higher that the output voltage when the MOSFET turns off. Thus, a MOSFET with enough voltage margin is needed. The RDS(ON) of the MOSFET is critical for power dissipation and current limit. A MOSFET with low RDS(ON) is desired to get high efficiency and output current, but very low RDS(ON) will reduce the loop stability. A MOSFET with 20m to 50m RDS(ON) is recommended. Some recommended MOSFETs are shown in following table. TABLE 2. RECOMMENDED MOSFETs PART NUMBER For low ESR ceramic capacitors, the output ripple is dominated by the charging and discharging of the output capacitor. The voltage rating of the output capacitor should be greater than the maximum output voltage. MANUFACTURER FEATURE FDC655AN Fairchild Semiconductor 6.3A, 30V, RDS(ON) = 23m FDS4488 Fairchild Semiconductor 7.9A, 30V, RDS(ON) = 22m Si7844DP Vishay 10A, 30V, RDS(ON) = 22m SI6928DQ Vishay 20A, 30V, RDS(ON) = 30m Rectifier Diode A high-speed diode is desired due to the high switching frequency. Schottky diodes are recommended because of their fast recovery time and low forward voltage. The rectifier diode must meet the output current and peak inductor current requirements. Output Capacitor The output capacitor supplies the load directly and reduces the ripple voltage at the output. Output ripple voltage consists of two components: the voltage drop due to the inductor ripple current flowing through the ESR of output capacitor, and the charging and discharging of the output capacitor. The EL7520, EL7520A include three independent linearregulator controllers, in which two are positive output voltage (VON and VLOGIC), and one is negative. The VON, VOFF, and VLOGIC linear-regulator controller functional diagrams, applications circuits are shown in Figures 27, 28, and 29 respectively. Calculation of the Linear Regulator Base-Emitter Resistors (RBL, RBP and RBN) For the pass transistor of the linear regulator, low frequency gain (Hfe) and unity gain freq. (fT) are usually specified in the datasheet. The pass transistor adds a pole to the loop transfer function at fp = fT/Hfe. Therefore, in order to maintain phase margin at low frequency, the best choice for a pass device is often a high frequency low gain switching transistor. Further improvement can be obtained by adding a base-emitter resistor RBE (RBP, RBL, RBN in the Functional Block Diagram), which increase the pole frequency to: fp = fT*(1+ Hfe *re/RBE)/Hfe, where re = KT/qIc. So choose the lowest value RBE in the design as long as there is still enough base current (IB) to support the maximum output current (IC). We will take as an example the VLOGIC linear regulator. If a Fairchild FMMT549 PNP transistor is used as the external pass transistor, Q31 in the application diagram, then for a maximum VLOGIC operating requirement of 500mA the data sheet indicates Hfe_min = 100. The base-emitter saturation voltage is: Vbe_max = 1.25V (note this is normally a Vbe ~ 0.7V, however, for the Q5 transistor an internal Darlington arrangement is used to increase it's current gain, giving a 'base-emitter' voltage of 2 x VBE). (Note that using a high current Darlington PNP transistor for Q5 requires that VIN > VLOGIC + 2V. Should a lower input voltage be required, then an ordinary high gain PNP transistor should be selected for Q5 so as to allow a lower collector-emitter saturation voltage). For the EL7520, EL7520A, the minimum drive current is: I_DRVL_min = 8mA IO V O – V IN 1 V RIPPLE = I LPK ESR + ------------------------ ---------------- ----f V C O FN7318 Rev 0.00 July 12, 2005 OUT S Page 12 of 18 EL7520, EL7520A The minimum base-emitter resistor, RBL, can now be calculated as: VIN OR VPROT (3V TO 6V) RBL_min = VBE_max/(I_DRVL_min - Ic/Hfe_min) = 1.25V/(8mA - 500mA/100) = 417 LDO_LOG 0.9V This is the minimum value that can be used - so, we now choose a convenient value greater than this minimum value; say 500. Larger values may be used to reduce quiescent current, however, regulation may be adversely affected, by supply noise if RBL is made too high in value. VBOOST LX 0.1µF PG_LDOL RBL 500 + - Q5 VLOGIC (1.3V TO 3.6V) DRVL RL1 CLOG 10µF FBL + GML RL2 20k LDO_ON 0.9V 1: N1 PG_LDOP 36V ESD CLAMP + - CP (TO 36V) RBP 7k 0.1µF Q3 VON (TO 35V) DRVP RP1 FBP CON RP2 20k + GMP 1: Np FIGURE 27. VON FUNCTIONAL BLOCK DIAGRAM LX 0.1µF CP (TO -26V) LDO_OFF PG_LDON 0.4V VREF + FBN 1: Nn 0.1µF RN2 20k RN1 VOFF (TO -20V) + GMN DRVN 36V ESD CLAMP RBN 3k Q2 COFF FIGURE 28. VOFF FUNCTIONAL BLOCK DIAGRAM FN7318 Rev 0.00 July 12, 2005 FIGURE 29. VLOGIC FUNCTIONAL BLOCK DIAGRAM The VON power supply is used to power the positive supply of the row driver in the LCD panel. The DC/DC consists of an external diode-capacitor charge pump powered from the inductor (LX) of the boost converter, followed by a low dropout linear regulator (LDO_ON). The LDO_ON regulator uses an external PNP transistor as the pass element. The onboard LDO controller is a wide band (>10MHz) transconductance amplifier capable of 4mA drive current, which is sufficient for up to 40mA or more output current under the low dropout condition (forced beta of 10). Typical VON voltage supported by EL7520, EL7520A range from +15V to +36V. A fault comparator is also included for monitoring the output voltage. The under-voltage threshold is set at 25% below the 1.2V reference. The VOFF power supply is used to power the negative supply of the row driver in the LCD panel. The DC/DC consists of an external diode-capacitor charge pump powered from the inductor (LX) of the boost converter, followed by a low dropout linear regulator (LDO_OFF). The LDO_OFF regulator uses an external NPN transistor as the pass element. The onboard LDO controller is a wide band (>10MHz) transconductance amplifier capable of 4mA drive current, which is sufficient for up to 40mA or more output current under the low dropout condition (forced beta of 10). Typical VOFF voltage supported by EL7520, EL7520A range from -5V to -20V. A fault comparator is also included for monitoring the output voltage. The undervoltage threshold is set at 200mV above the 0.2V reference level. The VLOGIC power supply is used to power the logic circuitry within the LCD panel. The DC/DC may be powered directly from the low voltage input, 3.3V or 5.0V, or it may be powered through the fault protection switch. The LDO_LOGIC regulator uses an external PNP transistor as the pass element. The onboard LDO controller is a wide band (>10MHz) transconductance amplifier capable of 16mA drive current, which is sufficient for up to 160mA or more output current Page 13 of 18 EL7520, EL7520A under the low dropout condition (forced beta of 10). Typical VLOGIC voltage supported by EL7520, EL7520A range from +1.3V to VDD-0.2V. A fault comparator is also included for monitoring the output voltage. The undervoltage threshold is set at 25% below the 1.2V reference. Set-Up LDOs Output Voltage Refer to Typical Application Diagram, the output voltages of VON, VOFF, and VLOGIC are determined by the following equations: R 12 V ON = V REF 1 + ---------- R 11 R 22 V OFF = V REFN + ---------- V REFN – V REF R 21 R 42 V LOGIC = V REF 1 + ---------- R 41 Where VREF = 1.2V, VREFN = 0.2V. Charge Pump To generate an output voltage higher than VBOOST, single or multi stages of charge pumps are needed. The number of stage is determined by the input and output voltage. For positive charge pump stages: V OUT + V CE – V INPUT N POSITIVE -------------------------------------------------------------V INPUT – 2 V F where VCE is the dropout voltage of the pass component of the linear regulator. It ranges from 0.3V to 1V depending on the transistor. VF is the forward-voltage of the charge pump rectifier diode. The number of negative charge pump stages is given by: V OUTPUT + V CE N NEGATIVE ------------------------------------------------V INPUT – 2 V F To achieve high efficiency and low material cost, the lowest number of charge pump stages, which can meet the above requirements, is always preferred. Charge Pump Output Capacitors A ceramic capacitor with low ESR is recommended. With ceramic capacitors, the output ripple voltage is dominated by the capacitance value. The capacitance value can be chosen by the following equation: Start-Up Sequence Figures 30 and 31 show detailed start-up sequence waveforms, EL7520 and EL7520A, respectively. For a successful power-up, there should be six peaks at VCDLY. When a fault is detected, the device will latch off until either EN is toggled or the input supply is recycled. If EN is L, the device is powered down. If EN is H, and the input voltage (VDD) exceeds 2.5V, an internal current source starts to charge CDLY to an upper threshold using a fast ramp followed by a slow ramp. If EN is low at this point, the CDLY ramp will be delayed until EN goes high. The first four ramps on CDLY (two up, two down) are used to initialize the fault protection switch and to check whether there is a fault condition on CDLY or VREF. If a fault is detected, the outputs and the input protection will turn off and the chip will power down. For EL7520A, VREF will stay on. If no fault is found, CCDLY continues ramping up and down until the sequence is completed. During the second ramp, the device checks the status of VREF and over temperature. At the peak of the second ramp, PG output goes low and enables the input protection PMOS Q1. Q1 is a controlled FET used to prevent in-rush current into VBOOST before VBOOST is enabled internally. Its rate of turn on is controlled by Co. When a fault is detected, Q1 will turn off and disconnect the inductor from VIN. With the input protection FET on, NODE1 (See Typical Application Diagram) will rise to ~VIN. Initially the boost is not enabled so VBOOST rises to VIN-VDIODE through the output diode. Hence, there is a step at VBOOST during this part of the start-up sequence. If this step is not desirable, an external PMOS FET can be used to delay the output until the boost is enabled internally. The delayed output appears at AVDD. For EL7520, VBOOST and VLOGIC soft-start at the beginning of the third ramp. The soft-start ramp depends on the value of the CDLY capacitor. For CDLY of 220nF, the soft-start time is ~2ms. EL7520A is the same as EL7520 except that VREF and VLOGIC turn on once input voltage exceeds 2.5V. VOFF turns on at the start of the fourth peak. At the fifth peak, DELB gate goes low to turn on the external PMOS Q4 to generate a delayed VBOOST output. VON is enabled at the beginning of the sixth ramp. AVDD, PG, VOFF, DELB and VON are checked at end of this ramp. I OUT C OUT -----------------------------------------------------2 V RIPPLE f OSC Where fSOC is the switching frequency. FN7318 Rev 0.00 July 12, 2005 Page 14 of 18 CHIP DISABLED FAULT DETECTED VON SOFT-START DELB ON VOFF ON AVDD, VLOGIC SOFT-START PG ON VREF ON EL7520, EL7520A VCDLY EN VREF VBOOST tON tOS VLOGIC VOFF tDEL1 DELAYED VBOOST tDEL2 FAULT PRESENT START-UP SEQUENCE TIMED BY CDLY NORMAL OPERATION VON FIGURE 30. EL7520 START-UP SEQUENCE FN7318 Rev 0.00 July 12, 2005 Page 15 of 18 CHIP DISABLED FAULT DETECTED VON SOFT-START DELB ON VOFF ON AVDD SOFT-START PG ON VREF, VLOGIC ON EL7520, EL7520A VCDLY VIN EN VREF VBOOST tON tOS VLOGIC VOFF tDEL1 DELAYED VBOOST tDEL2 START-UP SEQUENCE TIMED BY CDLY FAULT PRESENT tDEL3 NORMAL OPERATION VON FIGURE 31. EL7520A START-UP SEQUENCE FN7318 Rev 0.00 July 12, 2005 Page 16 of 18 EL7520, EL7520A Over-Temperature Protection An internal temperature sensor continuously monitor the die temperature. In the event that the die temperature exceeds the thermal trip point, the device will shut down. The upper and lower trigger points are typically set to 130°C and -90°C respectively. Layout Recommendation The device's performance including efficiency, output noise, transient response and control loop stability is dramatically affected by the PCB layout. PCB layout is critical, especially at high switching frequency. There are some general guidelines for layout: 1. Place the external power components (the input capacitors, output capacitors, boost inductor and output diodes, etc.) in close proximity to the device. Traces to these components should be kept as short and wide as possible to minimize parasitic inductance and resistance. 2. Place VREF and VDD bypass capacitors close to the pins. 3. Reduce the loop with large AC amplitudes and fast slew rate. 4. The feedback network should sense the output voltage directly from the point of load, and be as far away from LX node as possible. 5. The power ground (PGND) and signal ground (SGND) pins should be connected at only one point. A demo board is available to illustrate the proper layout implementation. FN7318 Rev 0.00 July 12, 2005 Page 17 of 18 EL7520, EL7520A QFN Package Outline Drawing NOTE: The package drawing shown here may not be the latest version. To check the latest revision, please refer to the Intersil website at <http://www.intersil.com/design/packages/index.asp> © Copyright Intersil Americas LLC 2005. All Rights Reserved. All trademarks and registered trademarks are the property of their respective owners. For additional products, see www.intersil.com/en/products.html Intersil products are manufactured, assembled and tested utilizing ISO9001 quality systems as noted in the quality certifications found at www.intersil.com/en/support/qualandreliability.html Intersil products are sold by description only. Intersil may modify the circuit design and/or specifications of products at any time without notice, provided that such modification does not, in Intersil's sole judgment, affect the form, fit or function of the product. Accordingly, the reader is cautioned to verify that datasheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com FN7318 Rev 0.00 July 12, 2005 Page 18 of 18