SC4524E 28V 2A Step-Down Switching Regulator POWER MANAGEMENT Features Description Wide Input Voltage Range: 3V to 28V 2A Output Current 200kHz to 2MHz Programmable Frequency Precision 1V Feedback Voltage Peak Current-Mode Control Cycle-by-Cycle Current Limiting Hiccup Overload Protection with Frequency Foldback Soft-Start and Enable Thermal Shutdown Thermally Enhanced 8-pin SOIC Package Fully RoHS and WEEE Compliant Applications XDSL and Cable Modems Set Top Boxes Point of Load Applications CPE Equipment DSP Power Supplies LCD and Plasma TVs Automotive Car Audio The SC4524E is a constant frequency peak current-mode step-down switching regulator capable of producing 2A output current from an input ranging from 3V to 28V. The switching frequency of the SC4524E can be programmed up to 2MHz for component miniaturization or it can be set at lower frequencies to accommodate high step-down ratios. The SC4524E is suitable for next generation XDSL modems, high-definition TVs and various point of load applications. Peak current-mode PWM control employed in the SC4524E achieves fast transient response with simple loop compensation. Cycle-by-cycle current limiting and hiccup overload protection reduces power dissipation during output overload. Soft-start function reduces input startup current and prevents the output from overshooting during power-up. The SC4524E is available in SOIC-8 EDP package. S S 270 RE V 4 Typical Application Circuit Efficiency IN 10 V – 28 V C4 2 .2mF SW S C 4 5 2 4E S S /E N 85 1N 4148 C1 0.33mF L1 BST IN 90 8 .2mH R4 42 .2 k 5 V /2 A FB COMP C7 10 nF C8 22 pF ROSC R7 28 .0k GND R5 15 .8k D2 20 B Q 030 80 OUT R6 10.5k Efficiency (%) V D1 C2 22mF V IN = 12V V IN = 24V 70 65 60 55 50 45 C5 2 .2 nF L1 : C oiltronics D R 73 - 8R 2 75 40 0 C 2: M urata G R M 31C R 60 J226 K C 4: M urata G R M 31 C R 71H 225 K 0.5 1 1.5 2 Load Current (A) Figure 1. 1MHz 10V-28V to 5V/2A Step-down Converter Rev. 2.0 © 2013 Semtech Corporation F ig.1 E fficiency o f th e 1 M H z 1 0V -2 8V to 5 V /2A S tep -D o SC4524E Pin Configuration Ordering Information SW 1 8 BST IN 2 7 FB ROSC 3 6 COMP GND 4 5 S S /E N 9 Device Package SC4524ESETRT(1)(2) SOIC-8 EDP SC4524EEVB Evaluation Board Notes: (1) Available in tape and reel only. A reel contains 2,500 devices. (2) Available in lead-free package only. Device is fully WEEE and RoHS compliant and halogen-free. (8 - Pin SOIC - EDP) Marking Information yyww=Date code (Example: 0752) xxxxx=Semtech Lot No. (Example: E9010) SC4524E Absolute Maximum Ratings Thermal Information VIN Supply Voltage …………………………… .… -0.3 to 32V Junction to Ambient (1) ……………………………… 36°C/W BST Voltage ……………………………………………… 42V Junction to Case (1) ………………………………… BST Voltage above SW …………………………………… 36V Maximum Junction Temperature……………………… 150°C 5.5°C/W Storage Temperature ………………………… -65 to +150°C SS Voltage ……………………………………………-0.3 to 3V Lead Temperature (Soldering) 10 sec ………………… 300°C FB Voltage ………………………………………. . . . -0.3 to 7V Recommended Operating Conditions SW Voltage ………………………………………… -0.6 to VIN SW Transient Spikes (10ns Duration)……… -2.5V to VIN +1.5V Input Voltage Range ……………………………… 3V to 28V Peak IR Reflow Temperature …………………………. Maximum Output Current ……………………………… 2A 260°C ESD Protection Level ………………………………… 2000V (2) Operating Ambient Temperature …………… -40 to +105°C Operating Junction Temperature …………… -40 to +125°C Exceeding the above specifications may result in permanent damage to the device or device malfunction. Operation outside of the parameters specified in the Electrical Characteristics section is not recommended. NOTES(1) Calculated from package in still air, mounted to 3” x 4.5”, 4 layer FR4 PCB with thermal vias under the exposed pad per JESD51 standards. (2) Tested according to JEDEC standard JESD22-A114-B. Electrical Characteristics Unless otherwise noted, VIN = 12V, VBST = 15V, VSS = 2.2V, -40°C < TJ < 125°C, ROSC = 12.1kΩ. Parameter Conditions Min Typ Max Units 28 V 2.95 V Input Supply Input Voltage Range VIN Start Voltage 3 VIN Rising 2.70 VIN Start Hysteresis VIN Quiescent Current VIN Quiescent Current in Shutdown 2.82 225 mV VCOMP = 0 (Not Switching) 2 2.6 mA VSS/EN = 0, VIN = 12V 40 52 µA 1.000 1.020 V Error Amplifier Feedback Voltage Feedback Voltage Line Regulation FB Pin Input Bias Current 0.980 VIN = 3V to 28V 0.005 VFB = 1V, VCOMP = 0.8V -170 %/V -340 nA Error Amplifier Transconductance 300 µΩ-1 Error Amplifier Open-loop Gain 60 dB COMP Pin to Switch Current Gain 10 A/V VFB = 0.9V 2.4 V COMP Source Current VFB = 0.8V, VCOMP = 0.8V 17 COMP Sink Current VFB = 1.2V, VCOMP = 0.8V 25 COMP Maximum Voltage µA Internal Power Switch Switch Current Limit Switch Saturation Voltage (Note 1) ISW = -2.6A 2.6 3.3 4.3 A 250 400 mV SC4524E Electrical Characteristics (Cont.) Unless otherwise noted, VIN = 12V, VBST = 15V, VSS = 2.2V, -40°C < TJ < 125°C, ROSC = 12.1kΩ. Parameter Conditions Min Typ Max Units Minimum Switch On-time VIN = 10V, RSW = 10Ω 70 120 230 ns Minimum Switch Off-time VIN = 6V, RSW = 6Ω 30 75 130 ns 10 µA Switch Leakage Current Minimum Bootstrap Voltage ISW = -2.6A 1.8 2.3 V BST Pin Current ISW = -2.6A 60 95 mA Oscillator Switching Frequency Foldback Frequency ROSC = 12.1kΩ 1.04 1.3 1.56 MHz ROSC = 73.2kΩ 230 300 370 kHz ROSC = 12.1kΩ, VFB = 0 100 ROSC = 73.2kΩ, VFB = 0 35 60 90 0.2 0.3 0.4 V 0.95 1.2 1.4 V 250 kHz Soft Start and Overload Protection SS/EN Shutdown Threshold SS/EN Switching Threshold Soft-start Charging Current VFB = 0 V VSS/EN = 0 V VSS/EN = 1.5 V 1.9 1.6 Soft-start Discharging Current 2.4 3.2 µA 1.5 µA Hiccup Arming SS/EN Voltage VSS/EN Rising 2.15 V Hiccup SS/EN Overload Threshold VSS/EN Falling 1.9 V Hiccup Retry SS/EN Voltage VSS/EN Falling 0.6 1.0 1.2 V Over Temperature Protection Thermal Shutdown Temperature 165 °C Thermal Shutdown Hysteresis 10 °C Note 1: Switch current limit does not vary with duty cycle. SC4524E Pin Descriptions SO-8 Pin Name Pin Function 1 SW Emitter of the internal NPN power transistor. Connect this pin to the inductor, the freewheeling diode and the bootstrap capacitor. 2 IN Power supply to the regulator. It is also the collector of the internal NPN power transistor. It must be closely bypassed to the ground plane with a capacitor. 3 ROSC An external resistor from this pin to ground sets the oscillator frequency. 4 GND Ground pin 5 SS/EN Soft-start and regulator enable pin. A capacitor from this pin to ground provides soft-start and overload hiccup functions. Hiccup can be disabled by overcoming the internal soft-start discharging current with an external pullup resistor connected between the SS/EN and the IN pins. Pulling the SS/EN pin below 0.2V completely shuts off the regulator to low current state. 6 COMP The output of the internal error amplifier. The voltage at this pin controls the peak switch current. A RC compensation network at this pin stabilizes the regulator. 7 FB The inverting input of the error amplifier. If VFB falls below 0.8V, then the switching frequency will be reduced to improve short-circuit robustness (see Applications Information for details). 8 BST Supply pin to the power transistor driver. Tie to an external diode-capacitor bootstrap circuit to generate drive voltage higher than VIN in order to fully enhance the internal NPN power transistor. 9 Exposed Pad The exposed pad serves as a thermal contact to the circuit board. While the exposed pad is electrically isolated, it is suggested to be soldered to the ground plane of the PC board. SC4524E Block Diagram IN SLO PE COMP COMP 6 + 2 + S + IS E N 5 .5m W FB + EA + 7 OC IL IM + 1 8m V - BST V1 8 + PW M - S R FREQ UENCY F O LD B A C K ROSC Q POW ER T R A N S IS T O R CLK O S C IL L A T O R 3 1.2 V 1 R R SW O VERLO AD - PW M A1 + S S /E N 5 1V 1 .9V REFERENCE & THERM AL SHUTDO W N FAULT S O F T -S T A R T AND O VERLO AD H IC C U P CONTROL GND 4 Figure 2 — SC4524E Block Diagram 1.9 V S S /E N IC 2 .4mA B4 + S B1 O VERLO AD S OC R PW M R B2 1V /2 .1 5V FAULT Q ID 3 .9 mA _ Q B3 Figure 3 — Soft-start and Overload Hiccup Control Circuit SC4524E Typical Characteristics Efficiency V O = 5V 85 70 V O = 1.5V 65 60 55 45 40 75 V O = 2 .5 V 70 65 60 1M H z, V IN = 2 4V D 2 = 2 0B Q 0 3 0 50 45 0 0 .5 1 1.5 0 .5 1 1.5 Load Current (A) 2 -5 0 Frequency vs Temperature Normalized Frequency Normalized Frequency ROSC (k) 1 .1 R O S C = 7 3.2 k 1 .0 R O S C = 1 2.1 k 0 .9 0 25 50 75 100 125 Foldback Frequency vs VFB 1 .2 5 V IN = 1 2V 10 -2 5 Temperature (oC) 1 .2 100 0 .9 9 0 .9 7 0 Frequency Setting Resistor vs Frequency 1 .0 0 0 .9 8 40 2 Load Current (A) 1000 1 .0 1 V O = 3 .3 V 55 1 M H z,VIN = 1 2V D 2 = 2 0B Q 0 3 0 50 VO =5V 80 V O = 2.5V 75 Efficiency (%) Efficiency (%) 80 1 .0 2 V IN = 1 2 V 85 V O = 3.3V Feedback Voltage vs Temperature Efficiency 90 VFB (V) 90 1 R O S C = 7 3.2 k 0 .7 5 0 .5 TA = 2 5o C 0 .2 5 R O S C = 1 2 .1 k 1 0 0 .8 0 0 .2 5 0.5 0 .7 5 1 1 .2 5 1 .5 1 .7 5 2 -5 0 -2 5 0 Frequency (MHz) 50 75 100 0 .0 0 125 0 .2 0 0 .4 0 O 0 .6 0 0 .8 0 1 .0 0 VF B (V) Temperature ( C) Switch Saturation Voltage vs Switch Current 300 25 Switch Current Limit vs Temperature 4 .5 1 0 0.0 BST Pin Current vs Switch Current V IN = 1 2 V 25o C 200 -4 0 oC 150 4 .0 BST Pin Current (mA) V CESAT (mV) 250 Current Limit (A) 1 2 5o C 3 .5 3 .0 100 2 .5 50 0 .0 0.5 1 .0 1.5 2 .0 Switch Current (A) 2 .5 V BST =15V 7 5 .0 5 0 .0 -4 0 o C 1 2 5o C 2 5 .0 0 .0 -5 0 -2 5 0 25 50 75 Temperature ( OC) 100 125 0 0 .5 1 1 .5 2 2 .5 3 Switch Current (A) SC4524E Curve 12 Curve 11 Typical Characteristics (Cont.) S S 270 RE V 6-7 S S 270 RE V 6-7 S S 270 RE V 6-7 VIN Supply Current vs Soft-Start Voltage VIN Thresholds vs Temperature 2.5 S ta rt 2.8 2.7 2.6 80 -40 o C 1.5 1.0 Curve 14 0.5 2.4 0.0 U VL O 2.5 -50 -25 0 25 50 75 100 0 125 0.5 125 o C 40 0 1 1.5 0 2 5 10 20 25 30 S S 270 RE V 6-7 Soft-Start Charging Current vs Soft-Start Voltage SS Shutdown Threshold vs Temperature VIN Quiescent Current vs VIN 0.40 125 o C 15 VIN (V) S S 270 R E V 6-7 2.5 -40 o C VSS (V) Temperature ( C) S S 2 7 0 R E V 6 -7 60 20 Curve 15 o 0.0 -0.5 SS Threshold (V) -40 o C 1.5 1.0 0.5 0.35 Current (uA) 2.0 Current (mA) V SS = 0 125 o C 2.0 Current (mA) VIN Threshold (V) 2.9 VIN Shutdown Current vs VIN 100 Current (uA) 3.0 0.30 15 VIN (V) 20 25 -2.0 -3.0 0.20 10 -40 o C -1.5 -2.5 0.0 5 125 o C 0.25 V C O MP = 0 0 -1.0 30 -50 -25 0 25 50 75 o Temperature ( C) 100 125 0 0.5 1 1.5 2 VSS (V) SC4524E Applications Information Operation The SC4524E is a constant-frequency, peak current-mode, step-down switching regulator with an integrated 28V, 2.6A power NPN transistor. Programmable switching frequency makes the regulator design more flexible. With the peak current-mode control, the double reactive poles of the output LC filter are reduced to a single real pole by the inner current loop. This simplifies loop compensation and achieves fast transient response with a simple Type-2 compensation network. As shown in Figure 2, the switch collector current is sensed with an integrated 5.5mW sense resistor. The sensed current is summed with a slope-compensating ramp before it is compared with the transconductance error amplifier (EA) output. The PWM comparator trip point determines the switch turn-on pulse width. The current-limit comparator ILIM turns off the power switch when the sensed signal exceeds the 18mV current-limit threshold. Driving the base of the power transistor above the input power supply rail minimizes the power transistor saturation voltage and maximizes efficiency. An external bootstrap circuit (formed by the capacitor C1 and the diode D1 in Figure 1) generates such a voltage at the BST pin for driving the power transistor. Shutdown and Soft-Start The SS/EN pin is a multiple-function pin. An external capacitor connected from the SS pin to ground sets the soft-start and overload shutoff times of the regulator (Figure 3). The effect of VSS/EN on the SC4524E is summarized in Table 1. Table 1: SS/EN operation modes SS/EN Mode Supply Current <0.2V Shutdown 18uA @ 5Vin 0.4V to 1.2V Not switching 2mA 1.2V to 2.15V Switching & hiccup disabled >2.15V Switching & hiccup armed Load dependent Pulling the SS/EN pin below 0.2V shuts off the regulator and reduces the input supply current to 18µA (VIN = 5V). When the SS/EN pin is released, the soft-start capacitor is charged with an internal 1.9µA current source (not shown in Figure 3). As the SS/EN voltage exceeds 0.4V, the internal bias circuit of the SC4524E turns on and the SC4524E draws 2mA from VIN. The 1.9µA charging current turns off and the 2.4µA current source IC in Figure 3 slowly charges the soft-start capacitor. The error amplifier EA in Figure 2 has two non-inverting inputs. The non-inverting input with the lower voltage predominates. One of the non-inverting inputs is biased to a precision 1V reference and the other non-inverting input is tied to the output of the amplifier A1. Amplifier A1 produces an output V1 = 2(VSS/EN -1.2V). V1 is zero and COMP is forced low when VSS/EN is below 1.2V. During start up, the effective non-inverting input of EA stays at zero until the soft-start capacitor is charged above 1.2V. Once VSS/EN exceeds 1.2V, COMP is released. The regulator starts to switch when VCOMP rises above 0.4V. If the soft-start interval is made sufficiently long, then the FB voltage (hence the output voltage) will track V1 during start up. VSS/EN must be at least 1.83V for the output to achieve regulation. Proper soft-start prevents output overshoot. Current drawn from the input supply is also well controlled. Overload / Short-Circuit Protection Table 2 lists various fault conditions and their corresponding protection schemes in the SC4524E. Table 2: Fault conditions and protections Condition Fault Protective Action Cycle-by-cycle limit at IL>ILimit, V FB>0.8V Over current IL>ILimit, V FB<0.8V Over current VSS/EN Falling Persistent over current frequency foldback Shutdown, then retry SS/EN<1.9V or short circuit (Hiccup) Tj>160C Over temperature Shutdown programmed frequency Cycle-by-cycle limit with As summarized in Table 1, overload shutdown is disabled during soft-start (VSS/EN<2.15V). In Figure 3, the reset input of the overload latch B2 will remain high if the SS/EN voltage is below 2.15V. Once the soft-start capacitor is charged above 2.15V, the output of the Schmitt trigger B1 goes high, the reset input of B2 goes low and hiccup becomes armed. As the load draws more current from SC4524E Applications Information (Cont.) the regulator, the current-limit comparator ILIM (Figure 2) will eventually limit the switch current on a cycle-bycycle basis. The over-current signal OC goes high, setting the latch B3. The soft-start capacitor is discharged with (ID - IC) (Figure 3). If the inductor current falls below the current limit and the PWM comparator instead turns off the switch, then latch B3 will be reset and IC will recharge the soft-start capacitor. If over-current condition persists or OC becomes asserted more often than PWM over a period of time, then the soft-start capacitor will be discharged below 1.9V. At this juncture, comparator B4 sets the overload latch B2. The soft-start capacitor will be continuously discharged with (ID - IC). The COMP pin is immediately pulled to ground. The switching regulator is shut off until the soft-start capacitor is discharged below 1.0V. At this moment, the overload latch is reset. The soft-start capacitor is recharged and the converter again undergoes soft-start. The regulator will go through softstart, overload shutdown and restart until it is no longer overloaded. If the FB voltage falls below 0.8V because of output overload, then the switching frequency will be reduced. Frequency foldback helps to limit the inductor current when the output is hard shorted to ground. During normal operation, the soft-start capacitor is charged to 2.4V. Setting the Output Voltage The regulator output voltage is set with an external resistive divider (Figure 1) with its center tap tied to the FB pin. For a given R6 value, R4 can be found by V R4 = R6 O − 1 1.0V Setting the Switching Frequency The switching frequency of the SC4524E is set with an external resistor from the ROSC pin to ground. Table 3 lists standard resistor values for typical frequency setting. Table 3 — Resistor for Typical Switching Frequency Freq. (k) ROSC (k) Freq. (k) ROSC (k) Freq. (k) ROSC (k) 200 110 700 25.5 1400 9.76 250 84.5 800 21.5 1500 8.87 300 69.8 900 18.2 1600 8.06 350 57.6 1000 15.8 1700 7.15 400 49.9 1100 14.0 1800 6.34 500 38.3 1200 12.4 1900 5.62 600 30.9 1300 11.0 2000 5.23 Minimum On Time Consideration The operating duty cycle of a non-synchronous stepdown switching regulator in continuous-conduction mode (CCM) is given by D= VO + VD VIN + VD − VCESAT where VIN is the input voltage, VCESAT is the switch saturation voltage and VD is voltage drop across the rectifying diode. In peak current-mode control, the PWM modulating ramp is the sensed current ramp of the power switch. This current ramp is absent unless the switch is turned on. The intersection of this ramp with the output of the voltage feedback error amplifier determines the switch pulse width. The propagation delay time required to immediately turn off the switch after it is turned on is the minimum controllable switch on time (TON(MIN)). Closed-loop measurement shows that the SC4524E minimum on time is about 120ns at room temperature (Figure 4) for 1A load current. If the required switch on time is shorter than the minimum on time, the regulator will either skip cycles or it will jitter. To allow for transient headroom, the minimum operating switch on time should be at least 20% to 30% higher than the worst-case minimum on time. 10 SC4524E Applications Information (Cont.) equation and assuming 35% inductor ripple current, the inductor is given by L1 = ( VO + VD ) x (1 − D) 35 % x IO x FSW If the input voltage varies over a wide range, then choose L1 based on the nominal input voltage. Always verify converter operation at the input voltage extremes. The peak current limit of SC4524E power transistor is at least 2.6A. The maximum deliverable load current for the SC4524E is 2.6A minus one half of the inductor ripple current. Figure 4 — Variation of Minimum On Time with Ambient Temperature Minimum Off Time Limitation The PWM latch in Figure 2 is reset every cycle by the clock. The clock also turns off the power transistor to refresh the bootstrap capacitor. This minimum off time limits the attainable duty cycle of the regulator at a given switching frequency. The measured minimum off time is 138ns typically. If the required duty cycle is higher than the attainable maximum, then the output voltage will not be able to reach its set value in continuous-conduction mode. Inductor Selection The inductor ripple current for a non-synchronous stepdown converter in continuous-conduction mode is DIL = ( VO + VD ) x (1 − D) FSW x L1 where FSW is the switching frequency and L1 is the inductance. An inductor ripple current between 20% to 50% of the maximum load current gives a good compromise among efficiency, cost and size. Re-arranging the previous Input Decoupling Capacitor The input capacitor should be chosen to handle the RMS ripple current of a buck converter. This value is given by IRMS_ CIN = IO x D x (1 − D) The input capacitance must also be high enough to keep input ripple voltage within specification. This is important in reducing the conductive EMI from the regulator. The input capacitance can be estimated from CIN > IO 4 x DVIN x FSW where DVIN is the allowable input ripple voltage. Multi-layer ceramic capacitors, which have very low ESR (a few mW) and can easily handle high RMS ripple current, are the ideal choice for input filtering. A single 4.7µF X5R ceramic capacitor is adequate for 500kHz or higher switching frequency applications, and 10µF is adequate for 200kHz to 500kHz switching frequency. For high voltage applications, a small ceramic (1µF or 2.2µF) can be placed in parallel with a low ESR electrolytic capacitor to satisfy both the ESR and bulk capacitance requirements. Output Capacitor The output ripple voltage DVO of a buck converter can be expressed as 11 SC4524E Applications Information (Cont.) 1 DVO = DIL x ESR + 8 x FSW x CO where CO is the output capacitance. Since the inductor ripple current DIL increases as D decreases (see first Inductor selection equation), the output ripple voltage is therefore the highest when VIN is at its maximum. A 10µF to 47µF X5R ceramic capacitor is found adequate for output filtering in most applications. Ripple current in the output capacitor is not a concern because the inductor current of a buck converter directly feeds CO, resulting in very low ripple current. Avoid using Z5U and Y5V ceramic capacitors for output filtering because these types of capacitors have high temperature and high voltage coefficients. these transistors are to be driven into saturation, then their bases will have to be driven from a power supply higher in voltage than VIN. The required driver supply voltage (at least 2.3V higher than the SW voltage) is generated with a bootstrap circuit (the diode D1 and the capacitor C1 in Figure 6). The bootstrapped output (the common node between D1 and C1) is connected to the BST pin of the SC4524E. The minimum BST to SW voltage required to fully saturate the power transistor is shown in Figure 5. The minimum required VC1 increases as temperature decreases. The bootstrap circuit reaches equilibrium when the base charge drawn from C1 during transistor on time is equal to the charge replenished during the off interval. Freewheeling Diode Use of Schottky barrier diodes as freewheeling rectifiers reduces diode reverse recovery input current spikes, easing high-side current sensing in the SC4524E. These diodes should have an average forward current rating at least 2A and a reverse blocking voltage of at least a few volts higher than the input voltage. For switching regulators operating at low duty cycles (i.e. low output voltage to input voltage conversion ratios), it is beneficial to use freewheeling diodes with somewhat higher average current ratings (thus lower forward voltages). This is because the diode conduction interval is much longer than that of the transistor. Converter efficiency will be improved if the voltage drop across the diode is lower. Figure 5 — Typical Minimum Bootstrap Voltage required to Saturate Transistor (ISW= -2.6A) The 20BQ030 (International Rectifier), B230A (Diodes Inc.), SS13, SS23 (Vishay), CMSH1-40M, CMSH1-40ML and CMSH2-40M (Central-Semi.) are all suitable. Figure 6 summarizes various ways of bootstrapping the SC4524E. A fast switching PN diode (such as 1N4148 or 1N914) and a small (0.33μF – 0.47μF) ceramic capacitor can be used for D1 and C1 , respectively. The freewheeling diode should be placed close to the SW pin of the SC4524E on the PCB to minimize ringing due to trace inductance. Bootstrapping the Power Transistor To maximize efficiency, the turn-on voltage across the internal power NPN transistors should be minimized. If In Figure 6(a) the power switch is bootstrapped from the output. This is the most efficient configuration and it also results in the least voltage stress at the BST pin. The maximum BST pin voltage is about VIN + VOUT. The minimum VOUT required for this bootstrap configuration is 2.5V. If the output voltage is between 2.5V and 3V, then use a small Schottky diode (such as BAt54) for D1 to maximize the bootstrap voltage. 12 SC4524E D1 D1 BST V IN BST C1 VOUT V IN SC4524E SC4524E D2 GND GND D3 D3 D1 D1 + VZ - - VZ + BST BST C1 VOUT SW IN SC4524E GND V IN SC4524E D2 V S > V IN + 2 .5 V D1 BST C1 VOUT SW SC4524E D2 GND (e) D2 GND D1 IN VOUT (d) BST V IN C1 SW IN (c) V S > 2 .5 V D2 (b) (a) V IN VOUT SW IN SW IN C1 V IN VOUT SW IN SC4524E GND D2 (f) Figure 6(a)-(f). Methods of Bootstrapping the SC4524E 13 SC4524E Applications Information (Cont.) If VIN(MAX) + VOUT > 42V, then a Zener diode D3 can be used in series with D1 to lower the BST voltage [Figure 6(c)]. The following inequality gives a suitable range for the Zener voltage VZ: 9287 ! 9= ! 9,10$; 9287 The SC4524E can also be bootstrapped from the input [Figure 6(b)]. This configuration is not as efficient as Figure 6(a). However this may be the only option if the output voltage is less than 2.5V and there is no other supply with voltage higher than 2.5V. Voltage stress at the BST pin can be somewhat higher than 2VIN. The BST pin voltage should not exceed its absolute maximum rating of 42V. be high enough for the bootstrap circuit to run, especially at light loads. In order to have some inductor current to charge C1, the converter output needs to be loaded or VIN needs to be increased. Using larger soft-start capacitor CSS will also help the bootstrap circuit to run because there will be current in the inductor over a longer period of time. Figures 7(a) and 7(b) show the minimum input voltage required to start bootstrap and to run before dropping out as a function of the load current. The minimum start-up VIN decreases with higher dVIN/dt or larger soft-start capacitor CSS. The lines labeled “dropout” in these graphs show that once started, the bootstrap circuit is able to sustain itself down to zero load. To reduce BST voltage stress when stepping down from high VIN (>20V) to low VOUT (<2.5V), a Zener diode can be added in series with D1. This is shown in Figure 6(d). The Zener voltage can be selected as follows: 9,10,1 ! 9= ! 9,10$; Figures 6(e) and (f ) show how to bootstrap the SC4524E from a second independent power supply VS. The minimum bootstrap capacitance C1 can be estimated as: , ' & ! 2870$; I 96 where VS is the voltage applied to the anode of D1. (a) The inductor current charges the bootstrap capacitor when it pulls the SW node low during the switch off time. If D1 is connected to the converter input, then C1 will be charged as soon as VIN is applied. If the bootstrap diode is tied to the converter output [Figures 6(a) and 6(c)], then C1 can only be charged from the regulator output through the inductor. Before the converter starts, there is no output voltage or inductor current. Hence it is necessary for the regulator to deliver some inductor current to the output before C1 can be charged. If VIN is not much higher than the programmed VOUT and it ramps up very slowly, then the inductor current will not (b) Figure 7. The Minimum Input Voltage to Start and to Run Before Dropout. The Regulator is Bootstrapped from its Output [Figure 6(a)]. D1 is 1N4148. (a) VOUT = 5V (b) VOUT = 3.3V 14 SC4524E Applications Information (Cont.) Minimum Soft-start Capacitance CSS To ensure normal operation, the minimum soft-start capacitance CSS can be calculated in terms of the output capacitance CO and output load current IO according to the following equations. Substituting the first equation into the second equation, where VSS is the soft-start capacitor voltage and ISS is the soft-start charging current. V1 is the voltage defined in Figure 2. To ensure successful startup, the total current drawn from the output must be less than the maximum output capability of the part, the maximum load applied, the output voltage rise is observed using a 22nF for CSS. Adjust CSS until a linear VOUT ramp is achieved. Loop Compensation The goal of compensation is to shape the frequency response of the converter so as to achieve high DC accuracy and fast transient response while maintaining loop stability (see Figure 8). The block diagram in Figure 8 shows the control loops of a buck converter with the SC4524E. The inner loop (current loop) consists of a current sensing resistor (Rs=5.5mW) and a current amplifier (CA) with gain (GCA=18.5). The outer loop (voltage loop) consists of an error amplifier (EA), a PWM modulator, and a LC filter. Since the current loop is internally closed, the remaining task for the loop compensation is to design the voltage compensator (C5, R7, and C8). C O N T R O LLE R A N D S C H O T T K Y D IO D E CA REF Substituting the third equation of this section into the previous equation, Vc - Therefore the minimum CSS depends on the output capacitance and the load current. Larger CSS is necessary when starting into a heavy load (small R). If the regulator is to be started by turning on a bench power supply then CSS will be best determined empirically because the rise time of a power supply can range from a few milliseconds to a few hundred milliseconds. With PW M M O D U LA T O R SW V ram p L1 Vo COMP Co C5 C8 R7 Rearranging, Io + EA FB Rs R esr R4 R6 Figure 8. Block diagram of control loops For a converter with switching frequency FSW, output inductance L1, output capacitance CO and loading R, the control (VC) to output (VO) transfer function in Figure 8 is given by: GPWM (1 + sRESR CO ) Vo = Vc (1 + s / ωp )(1 + s / ωn Q + s2 / ωn2 ) This transfer function has a finite DC gain GPWM ≈ R GCA x RS 15 SC4524E Applications Information (Cont.) It has an ESR zero FZ at ωZ = Therefore, the procedure of the voltage loop design for the SC4524E can be summarized as: 1 (1) Plot the converter gain, i.e. control to feedback transfer function. (2) Select the open loop crossover frequency, FC, between 10% and 20% of the switching frequency. At FC, find the required compensator gain, AC. In typical applications with ceramic output capacitors, the ESR zero is neglected and the required compensator gain at FC can be estimated by R ESRCO It has a dominant low-frequency pole FP at ωp ≈ 1 RCO 1 V 1 x x FB AC = − 20 x log GCA RS 2πFC CO VO and double poles at half the switching frequency. Including the voltage divider (R4 and R6), the control to feedback transfer function is found and plotted in Figure 9 as the converter gain. Since the converter gain has only one dominant pole at low frequency, a simple Type-2 compensation network is sufficient for voltage loop compensation. As shown in Figure 9, the voltage compensator has a low frequency integrator pole, a zero at FZ1, and a high frequency pole at FP1. The integrator is used to boost the gain at low frequency. The zero is introduced to compensate the excessive phase lag at the loop gain crossover due to the integrator pole (-90deg) and the dominant pole (-90deg). The high frequency pole nulls the ESR zero and attenuates high frequency noise. 60 GAIN (dB) Fz1 Fp1 Fp CO NV -30 -60 1K AC 10 20 R7 = gm C5 = 1 2π FZ1 R7 C8 = 1 2 πFP1 R7 where gm=0.3mA/V is the EA gain of the SC4524E. 30 0 (3) Place the compensator zero, FZ1, between 10% and 20% of the crossover frequency, FC. (4) Use the compensator pole, FP1, to cancel the ESR zero, FZ. (5) Then, the parameters of the compensation network can be calculated by 10K ER T ER Fc LO CO MP OP G EN SA TO RG Example: Determine the voltage compensator for an 800kHz, 12V to 3.3V/2A converter with 22uF ceramic output capacitor. AIN AIN GA IN Fz Fsw/2 100K FREQUENCY (Hz) 1M 10M Choose a loop gain crossover frequency of 80kHz, and place voltage compensator zero and pole at FZ1=16kHz (20% of FC), and FP1=600kHz. From the equation in step (2), the required compensator gain at FC is $& · § ORJ¨¨ ¸ G% ¸ ʌ © ¹ Figure 9 — Bode plots for voltage loop design Then the compensator parameters are 16 SC4524E Applications Information (Cont.) 11.4 10 20 R7 = = 12.4 k 0.3 x 10−3 1 C5 = = 0.8 nF 3 2π x 16 x 10 x 12.4 x 103 1 = 21 pF 2 π x 600 x 103 x12.4 x 103 C8 = Select R7=12.4k, C5=1nF, and C8=22pF for the design. Compensator parameters for various typical applications are listed in Table 5. A MathCAD program is also available upon request for detailed calculation of the compensator parameters. Thermal Considerations For the power transistor inside the SC4524E, the conduction loss PC, the switching loss PSW, and bootstrap circuit loss PBST, can be estimated as follows: PC = D x VCESAT x IO 1 x t S x VIN x IO x FSW 2 I = D x VBSTx O 40 PSW = PBST where VBST is the BST supply voltage and tS is the equivalent switching time of the NPN transistor (see Table 4). (36oC/W), which is the thermal impedance from junction to ambient for the SOIC-8 EDP package. It is not recommended to operate the SC4524E above 125oC junction temperature. In the applications with high input voltage and high output current, the switching frequency may need to be reduced to meet the thermal requirement. PCB Layout Considerations In a step-down switching regulator, the input bypass capacitor, the main power switch and the freewheeling diode carry pulse currents (Figure 10). For jitter-free operation, the size of the loop formed by these components should be minimized. Since the power switch is already integrated within the SC4524E, connecting the anode of the freewheeling diode close to the negative terminal of the input bypass capacitor minimizes size of the switched current loop. The input bypass capacitor should be placed close to the IN pin. Shortening the traces of the SW and BST nodes reduces the parasitic trace inductance at these nodes. This not only reduces EMI but also decreases switching voltage spikes at these nodes. The exposed pad should be soldered to a large ground plane as the ground copper acts as a heat sink for the device. To ensure proper adhesion to the ground plane, avoid using large vias directly under the device. V IN Table 4: Typical switching time Input Voltage 12V 24V 28V Load Current 1A 2A 12.5ns 15.3ns 22ns 25ns 25.3ns 28ns VO U T Z L In addition, the quiescent current loss is PQ = VIN x 2mA The total power loss of the SC4524E is therefore PTOTAL = PC + PSW + PBST = PQ Figure 10 — Pulse current Loop Note: Heavy lines indicate the critical pulse current loop. The stray inductance of this loop should be minimized The temperature rise of the SC4524E is the product of the total power dissipation (see previous equation) and qJA 17 SC4524E Recommended Component Parameters in Typical Applications Table 5 lists the recommended inductance (L1) and compensation network (R7, C5, C8) for common input and output voltages. The inductance is determined by assuming that the ripple current is 35% of load current IO. The compensator parameters are calculated by assuming a 22mF low ESR ceramic output capacitor and a loop gain crossover frequency of FSW/10. 5. Recommended inductance (L1) and compensator (R7, C5, C8) SC4524CTable Compensator Parameters Vin(V) 12 24 Typical Applications Vo(V) Io(A) Fsw(kHz) 1 1.5 500 2 500 1 1000 2.5 500 2 1000 500 1 1000 3.3 500 2 1000 500 1 1000 5 500 2 1000 500 1 1000 7.5 500 2 1000 500 1 1000 10 500 2 1000 1 1.5 300 2 1 2.5 2 500 1 3.3 2 500 1 1000 5 500 2 1000 500 1 1000 7.5 500 2 1000 500 1 1000 10 500 2 1000 C2(uF) 22 Recommended Parameters L1(uH) R7(k) C5(nF) C8(pF) 8.2 4.32 3.3 10 4.7 15 6.81 1.5 22 6.8 12.1 0.82 10 6.8 6.81 1.5 22 3.3 12.1 0.68 10 15 9.09 1 22 8.2 18.7 0.68 10 8.2 9.09 1 22 4.7 18.7 0.68 15 14.3 0.82 10 24.9 0.68 8.2 14.3 0.82 4.7 27.4 0.68 15 21.5 0.82 10 8.2 38.3 0.68 8.2 21.5 0.82 4.7 38.3 0.68 10 25.5 0.82 4.7 51.1 0.68 4.7 25.5 0.82 2.2 51.1 0.68 10 5.49 3.3 47 8.2 15 7.5 1.5 8.2 10 22 9.09 1 10 22 12.1 0.82 22 15 26.1 0.68 10 10 12.1 0.82 22 6.8 26.1 0.68 10 33 21.5 0.82 15 38.3 0.68 10 21.5 0.82 22 8.2 38.3 0.68 10 22 26.1 0.82 22 10 51.1 0.68 10 10 26.1 0.82 22 8.2 51.1 0.68 10 18 SC4524E Typical Application Schematics V D1 D3 24 V IN 18 V Z ener 1N 4148 C4 4 .7mF C1 0.33mF BST IN SW OUT 8 .2mH S C 4 5 2 4E S S /E N L1 1.5V /2A R4 33.2k FB COMP C7 10 nF ROSC D2 R5 69 .8k R7 5 .49 k C8 47 pF GND 20 B Q 030 R6 66 .5 k C2 22mF C5 3 .3 nF L1 : C oiltronics D R 73 - 8 R 2 C 2: M urata G R M 31C R 60 J226 K C 4 : M urata G R M 32 E R 71 H 475 K Figure 11. 300kHz 24V to 1.5V/2A Step-down Converter V IN D1 10V – 26V C4 4.7mF 1N 4148 C1 0.33mF L1 BST IN SW 8.2mH S C 4524E S S /E N OUT 3.3V /2A R4 33.2k FB COMP C7 10nF C8 33pF R7 10.7k ROSC GND R5 25.5k D2 20B Q 030 R6 14.3k C2 22mF C5 1nF L1: C oiltronics D R 73 - 8R 2 C 2: M urata G R M 31C R 60J226M C 4: M urata G R M 32E R 71H 475K Figure 12. 700kHz 10V-26V to 3.3V/2A Step-down Converter 19 TR SC4524E Fig.12(b) SS Typical Performance Characteristics (For A 24V to 5V/2A Step-down Converter with 1MHz Switching Frequency) S S 2 7 0 R E V 6 -7 Load Characteristic 6 Output Voltage (V) 5 24V Input (10V/DIV) 4 3 5V Output (2V/DIV) 2 1 SS Voltage (1V/DIV) 0 0 0 .5 1 1 .5 2 2 .5 3 Load Current (A) Fig.12(d) OCP Load Characteristic 10ms/DIV VIN Start up Transient (IO=2A) 5V Output Short (5V/DIV) 5V Output Response (500mV/DIV, AC Coupling) Inductor Current (1A/DIV) Retry Inductor Current (2A/DIV) SS Voltage (2V/DIV) 40us/DIV Load Transient Response (IO= 0.3A to 2A) 20ms/DIV Output Short Circuit (Hiccup) 20 SC4524E Outline Drawing - SOIC-8 EDP A D e N 2X E /2 E1 1 E 2 ccc C 2 X N /2 T IP S e /2 B D aaa C S E A T IN G PLANE A2 A C b xN bbb A1 D IM E N S IO N S IN C H E S M ILLIM E T E R S D IM M IN N O M M A X M IN N O M M A X A A1 A2 b c D E1 E e F H h L L1 N 01 aaa bbb ccc .0 6 9 .0 0 5 .0 6 5 .0 2 0 .0 1 0 .1 9 3 .1 9 7 .1 5 4 .1 5 7 .2 3 6 B S C .0 5 0 B S C .1 1 6 .1 2 0 .1 3 0 .0 8 5 .0 9 5 .0 9 9 .0 1 0 .0 2 0 .0 1 6 .0 2 8 .0 4 1 (.0 4 1 ) 8 0° 8° .0 0 4 .0 1 0 .0 0 8 .0 5 3 .0 0 0 .0 4 9 .0 1 2 .0 0 7 .1 8 9 .1 5 0 C A -B D 1 .7 5 0 .1 3 1 .6 5 0 .5 1 0 .2 5 4 .9 0 5 .0 0 3 .9 0 4 .0 0 6 .0 0 B S C 1 .2 7 B S C 2 .9 5 3 .0 5 3 .3 0 2 .1 5 2 .4 1 2 .5 1 0 .2 5 0 .5 0 0 .4 0 0 .7 2 1 .0 4 (1 .0 5 ) 8 0° 8° 0 .1 0 0 .2 5 0 .2 0 1 .3 5 0 .0 0 1 .2 5 0 .3 1 0 .1 7 4 .8 0 3 .8 0 h F EXPOSED PAD h H H c GAGE PLANE 0 .2 5 L (L1 ) S E E D E T A IL S ID E V IE W A D E T A IL 01 A NO TES: 1. C O N T R O L L IN G D IM E N S IO N S A R E IN M IL L IM E T E R S (A N G L E S IN D E G R E E S ). 2. D A T U M S -A - A N D 3. D IM E N S IO N S "E 1 " A N D "D " D O N O T IN C L U D E M O L D F L A S H , P R O T R U S IO N S O R G ATE BURRS . R E F E R E N C E JE D E C S T D M S -0 1 2 , V A R IA T IO N B A . 4. -B - T O B E D E T E R M IN E D A T D A T U M P L A N E -H - 21 SC4524E Land Pattern - SOIC-8 EDP E SOLDER M ASK D D IM E N S IO N S D IM (C ) F G Z Y T H E R M A L V IA Ø 0 .3 6m m P X C D E F G P X Y Z IN C H E S (.2 0 5) .1 3 4 .2 0 1 .1 0 1 .1 1 8 .0 5 0 .0 2 4 .0 8 7 .2 9 1 M ILLIM E T E R S (5 .2 0 ) 3 .4 0 5 .1 0 2 .5 6 3 .0 0 1 .2 7 0 .6 0 2 .2 0 7 .4 0 NO TES: 1. T H IS L A N D P A T T E R N IS F O R R E F E R E N C E P U R P O S E S O N L Y. C O N S U L T Y O U R M A N U F A C T U R IN G G R O U P T O E N S U R E Y O U R C O M P A N Y 'S M A N U F A C T U R IN G G U ID E L IN E S A R E M E T. 2. R E F E R E N C E IP C -S M -7 8 2 A , R L P N O . 3 0 0 A . 3. T H E R M A L V IA S IN T H E L A N D P A T T E R N O F T H E E X P O S E D P A D S H A L L B E C O N N E C T E D T O A S Y S T E M G R O U N D P L A N E. F A IL U R E T O D O S O M A Y C O M P R O M IS E T H E T H E R M A L A N D/O R F U N C T IO N A L P E R F O R M A N C E O F T H E D E V IC E . 22 SC4524E © Semtech 2013 All rights reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner. The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor imply any license under patent or other industrial or intellectual property rights. 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