L6728 Single phase PWM controller with Power Good Features ■ Flexible power supply from 5 V to 12 V ■ Power conversion input as low as 1.5 V ■ 0.8 V internal reference ■ 0.8 % output voltage accuracy ■ High-current integrated drivers ■ Power Good output ■ Sensorless and programmable OCP across low-side RDS(on) ■ OV / UV protections ■ VSEN disconnection protection ■ Oscillator internally fixed at 300 kHz ■ LSless to manage pre-bias start-up ■ Adjustable output voltage ■ Disable function ■ Internal soft-start ■ DFN10 package DFN10 Description L6728 is a single-phase step-down controller with integrated high-current drivers that provides complete control logic and protection to realize in a simple way general DC-DC converters by using a compact DFN10 package. Device flexibility allows managing conversions with power input VIN as low as 1.5 V and device supply voltage ranging from 5 V to 12 V. L6728 provides simple control loop with voltage mode EA. The integrated 0.8 V reference allows regulating output voltages with ±0.8 % accuracy over line and temperature variations. Oscillator is internally fixed to 300 kHz. Applications ■ Memory and termination supply ■ Subsystem power supply (MCH, IOCH, PCI...) ■ CPU and DSP power supply ■ Distributed power supply ■ General DC-DC converters L6728 provides programmable dual level over current protection as well as over and under voltage protection. Current information is monitored across the low-side MOSFET RDS(on) saving the use of expensive and spaceconsuming sense resistors. PGOOD output easily provides real-time information on output voltage status, through VSEN dedicated output monitor. Table 1. Device summary Order codes Package L6728 Packaging Tube DFN10 L6728TR June 2008 Tape and reel Rev 3 1/31 www.st.com 1 Content L6728 Content 1 2 Typical application circuit and block diagram . . . . . . . . . . . . . . . . . . . . 4 1.1 Application circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 1.2 Block diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Pin description and connection diagrams . . . . . . . . . . . . . . . . . . . . . . . 5 2.1 Pin descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3 Thermal data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 4 Electrical specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 4.1 Absolute maximum ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 4.2 Electrical characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 5 Device description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 6 Driver section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 6.1 7 Soft-start . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 7.1 8 Power dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Low-side-less start up (LSLess) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Over current protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 8.1 Over current threshold setting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 9 Output voltage setting and protections . . . . . . . . . . . . . . . . . . . . . . . . 14 10 Application details . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 11 2/31 10.1 Compensation network . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 10.2 Layout guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 Application information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 11.1 Inductor design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 11.2 Output capacitor(s) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 11.3 Input capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 L6728 12 Content 20 A demonstration board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 12.1 13 Board description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 12.1.1 Power input (Vin) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 12.1.2 Output (Vout) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 12.1.3 Signal input (Vcc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 12.1.4 Test points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 12.1.5 Board characterization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 5 A demonstration board . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25 13.1 Board description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 13.1.1 Power input (Vin) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 13.1.2 Output (Vout) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 13.1.3 Signal input (Vcc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 13.1.4 Test points . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 13.1.5 Board characterization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28 14 Package mechanical data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 29 15 Revision history . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30 3/31 Typical application circuit and block diagram L6728 1 Typical application circuit and block diagram 1.1 Application circuit Figure 1. Typical application circuit VIN = 1.5V to 12V VCC = 5V to 12V CDEC 6 RPG VCC 7 COMP / DIS CF CP ROS RF 8 RFB BOOT PGOOD FB VSEN L6728 10 PGOOD UGATE PHASE LGATE / OC GND 9 CBULK CHF 3 HS 2 Vout L 4 COUT LS LOAD ROCSET 5 ROS 1 RFB L6728 Reference Schematic 1.2 Block diagram Block diagram VCC Figure 2. VSEN VOUT MONITOR PGOOD VOCTH OC CONTROL LOGIC & PROTECTIONS BOOT ADAPTIVE ANTI CROSS CONDUCTION CLOCK PWM 300 kHz OSCILLATOR HS UGATE PHASE VCC LS ERROR AMPLIFIER LGATE / OC GND + - L6728 FB IOCSET COMP / DIS 4/31 0.8V L6728 2 Pin description and connection diagrams Pin description and connection diagrams Figure 3. 2.1 Pin connection (top view) Pin descriptions Table 2. Pins description Pin # Name 1 BOOT HS driver supply. Connect through a capacitor (100 nF) to the floating node (LS-Drain) pin and provide necessary bootstrap diode from VCC. 2 PHASE HS driver return path, current-reading and adaptive-dead-time monitor. Connect to the LS drain to sense RDS(on) drop to measure the output current. This pin is also used by the adaptive-dead-time control circuitry to monitor when HS MOSFET is OFF. 3 UGATE HS driver output. Connect directly to HS MOSFET gate. 4 Function LGATE. LS driver output. Connect directly to LS MOSFET gate. OC. Over Current threshold set. During a short period of time following VCC rising over UVLO threshold, a 10 µA current is sourced from this pin. resistor greater than 5 kΩ to program OC LGATE / OC Connect to GND with an ROCSET Threshold. The resulting voltage at this pin is sampled and held internally as the OC set point. Maximum programmable OC threshold is 0.55 V. A voltage greater than 0.6 V activates an internal clamp and causes OC threshold to be set at the maximum value. 5 GND All internal references, logic and drivers are connected to this pin. Connect to the PCB ground plane. 6 VCC Device and drivers power supply. Operative range from 5 V to 12 V. Filter with at least 1 nF MLCC to GND. 7 8 COMP. Error amplifier output. Connect with an RF - CF // CP to FB to compensate the device control loop. COMP / DIS DIS. The device can be disabled by pushing this pin lower than 0.75 V(typ). Setting free the pin, the device enables again. FB Error amplifier inverting input. Connect with a resistor RFB to the output regulated voltage. Output resistor divider may be used to regulate voltages higher than the reference. 5/31 Thermal data L6728 Table 2. 3 Pin # Name 9 VSEN Regulated voltage sense pin for OVP and UVP protections and PGOOD. Connect to the output regulated voltage, or to the output resistor divider if the regulated voltage is higher than the reference. 10 PGOOD Open drain output set free after SS has finished and pulled low when VSEN is outside the relative window. Pull up to a voltage equal or lower than VCC. If not used it can be left floating. Function Thermal data Table 3. Symbol Thermal data Parameter Value Unit Rth(JA) Thermal resistance junction to ambient (Device soldered on 2s2p, 67 mm x 69 mm board) 45 °C/W Rth(JC) Thermal resistance junction to case 5 °C/W TMAX Maximum junction temperature 150 °C TSTG Storage temperature range -40 to 150 °C TJ Junction temperature range -40 to 125 °C 2.25 W PTOT 6/31 Pins description (continued) Maximum power dissipation at TA = 25 °C L6728 Electrical specifications 4 Electrical specifications 4.1 Absolute maximum ratings Table 4. Absolute maximum ratings Symbol Value Unit -0.3 to 15 V VBOOT, VUGATE to PHASE to GND to GND; t < 200 ns 15 33 45 V VPHASE to GND to GND; t < 200 ns -5 to 18 -8 to 30 V VLGATE to GND -0.3 to VCC+0.3 V -0.3 to 3.6 V -0.3 to VCC+0.3 V VCC Parameter to GND FB, COMP, VSEN to GND PGOOD to GND 4.2 Electrical characteristics Table 5. Electrical characteristics (VCC = 5 V to 12 V; TJ = 0 to 70 °C unless otherwise specified) Symbol Parameter Test conditions Min Typ Max Unit Supply current and power-ON ICC VCC supply current UGATE and LGATE = OPEN IBOOT BOOT supply current UGATE = OPEN; PHASE to GND VCC Turn-ON VCC rising 6 mA 0.7 mA 4.1 V UVLO Hysteresis 0.2 V Oscillator FSW Main oscillator accuracy ∆VOSC PWM ramp amplitude dMAX Maximum duty cycle 270 300 330 1.4 kHz V 80 % Reference and error amplifier Output voltage accuracy A0 GBWP DC gain -0.8 (1) Gain-bandwidth product (1) (1) SR Slew-rate DIS Disable threshold COMP falling 0.70 - 0.8 % 120 dB 15 MHz 8 V/µs 0.85 V 7/31 Electrical specifications Table 5. Symbol L6728 Electrical characteristics (continued) (VCC = 5 V to 12 V; TJ = 0 to 70 °C unless otherwise specified) Parameter Test conditions Min Typ Max Unit Gate drivers IUGATE HS source current BOOT - PHASE = 5 V 1.5 A RUGATE HS sink resistance BOOT - PHASE = 5 V 1.1 Ω ILGATE LS source current VCC = 5 V 1.5 A RLGATE LS sink resistance VCC = 5 V 0.65 Ω Over-current protection IOCSET OCSET current source Sourced from LGATE pin, during OC setting phase. VOC_SW OC switch-over threshold VLGATE/OC rising 9 10 11 600 µA mV Over and under-voltage protections OVP VSEN rising 0.90 1.00 1.10 V un-latch, VSEN falling 0.35 0.40 0.45 V 0.50 0.60 0.70 V OVP threshold UVP UVP threshold VSEN falling VSEN VSEN bias current Sourced from VSEN Upper threshold VSEN rising 0.860 0.890 0.920 V Lower threshold VSEN falling 0.680 0.710 0.740 V PGOOD voltage low IPGOOD = -4 mA 0.4 V 100 nA PGOOD PGOOD VPGOODL 1. Guaranteed by design, not subject to test. 8/31 L6728 5 Device description Device description L6728 is a single-phase PWM controller with embedded high-current drivers that provides complete control logic and protections to realize in an easy and simple way a general DCDC step-down converter. Designed to drive N-channel MOSFETs in a synchronous buck topology, with its high level of integration this 10-pin device allows reducing cost and size of the power supply solution also providing real-time PGOOD in a compact DFN10 3x3 mm. L6728 is designed to operate from a 5 V or 12 V supply. The output voltage can be precisely regulated to as low as 0.8 V with ±0.8 % accuracy over line and temperature variations. The switching frequency is internally set to 300 kHz. This device provides a simple control loop with a voltage-mode error-amplifier. The erroramplifier features a 15 MHz gain-bandwidth product and 8V/µs slew rate, allowing high regulator bandwidth for fast transient response. To avoid load damages, L6728 provides over current protection as well as over voltage, under voltage and feedback disconnection protection. The over current trip threshold is programmable by a simple resistor connected from Lgate to GND. Output current is monitored across low-side MOSFET RDS(on), saving the use of expensive and spaceconsuming sense resistor. Output voltage is monitored through dedicated VSEN pin. L6728 implements soft-start increasing the internal reference in closed loop regulation. Low-side-less feature allows the device to perform soft-start over pre-biased output avoiding high current return through the output inductor and dangerous negative spike at the load side. L6728 is available in a compact DFN10 3x3 mm package with exposed pad. 9/31 Driver section 6 L6728 Driver section The integrated high-current drivers allow using different types of power MOSFET (also multiple MOSFETs to reduce the equivalent RDS(on)), maintaining fast switching transition. The driver for the high-side MOSFET uses BOOT pin for supply and PHASE pin for return. The driver for low-side MOSFET uses the VCC pin for supply and GND pin for return. The controller embodies an anti-shoot-through and adaptive dead-time control to minimize low side body diode conduction time, maintaining good efficiency while saving the use of Schottky diode: ● to check high-side MOSFET turn off, PHASE pin is sensed. When the voltage at PHASE pin drops down, the low-side MOSFET gate drive is suddenly applied; ● to check low-side MOSFET turn off, LGATE pin is sensed. When the voltage at LGATE has fallen, the high-side MOSFET gate drive is suddenly applied. If the current flowing in the inductor is negative, voltage on PHASE pin will never drop. To allow the low-side MOSFET to turn-on even in this case, a watchdog controller is enabled: if the source of the high-side MOSFET doesn't drop, the low side MOSFET is switched on so allowing the negative current of the inductor to recirculate. This mechanism allows the system to regulate even if the current is negative. Power conversion input is flexible: 5 V, 12 V bus or any bus that allows the conversion (See maximum duty cycle limitations) can be chosen freely. 6.1 Power dissipation L6728 embeds high current MOSFET drivers for both high side and low side MOSFETs: it is then important to consider the power that the device is going to dissipate in driving them in order to avoid overcoming the maximum junction operative temperature. Two main terms contribute in the device power dissipation: bias power and drivers' power. ● Device bias power (PDC) depends on the static consumption of the device through the supply pins and it is simply quantifiable as follow (assuming to supply HS and LS drivers with the same VCC of the device): P DC = V CC ⋅ ( I CC + I BOOT ) ● Drivers power is the power needed by the driver to continuously switch on and off the external MOSFETs; it is a function of the switching frequency and total gate charge of the selected MOSFETs. It can be quantified considering that the total power PSW dissipated to switch the MOSFETs (easy calculable) is dissipated by three main factors: external gate resistance (when present), intrinsic MOSFET resistance and intrinsic driver resistance. This last term is the important one to be determined to calculate the device power dissipation. The total power dissipated to switch the MOSFETs results: P SW = F SW ⋅ ( Q gHS ⋅ V BOOT + Q gLS ⋅ V CC ) External gate resistors helps the device to dissipate the switching power since the same power PSW will be shared between the internal driver impedance and the external resistor resulting in a general cooling of the device. 10/31 L6728 7 Soft-start Soft-start L6728 implements a soft-start to smoothly charge the output filter avoiding high in-rush currents to be required from the input power supply. The device gradually increases the internal reference from 0 V to 0.8 V in 4.5 ms (typ.), in closed loop regulation, linearly charging the output capacitors to the final regulation voltage. In the event of an over current triggering during soft start, the over current logic will override the soft start sequence and will shut down the PWM logic and both the high side and low side gates. This condition is latched, cycle VCC to recover. The device begins soft start phase only when VCC power supply is above UVLO threshold and over current threshold setting phase has been completed. 7.1 Low-side-less start up (LSLess) In order to avoid any kind of negative undershoot and dangerous return from the load during start-up, L6728 performs a special sequence in enabling LS driver to switch: during the softstart phase, the LS driver results disabled (LS = OFF) until the HS starts to switch. This avoid the dangerous negative spike on the output voltage that can happen if starting over a pre-biased output. If the output voltage is pre-biased to a voltage higher than the final one, the HS would never start to switch. In this case, at the end of soft start time, LS is enabled and discharge the output to the final regulation value. This particular feature of the device masks the LS turn-on only from the control loop point of view: protections by-pass this turning ON the LS MOSFET in case of need. Figure 4. LSLess start up (left) vs non-LSLess start up (right) 11/31 Over current protection 8 L6728 Over current protection The over current function protects the converter from a shorted output or overload, by sensing the output current information across the low side MOSFET drain-source onresistance, RDS(on). This method reduces cost and enhances converter efficiency by avoiding the use of expensive and space-consuming sense resistors. The low side RDS(on) current sense is implemented by comparing the voltage at the PHASE node when LS MOSFET is turned on with the programmed OCP thresholds voltages, internally held. If the monitored voltage is bigger than these thresholds, an over current event is detected. For maximum safety and load protection, L6728 implements a dual level over current protection system: ● 1st level threshold: it is the user externally set threshold. If the monitored voltage on PHASE exceeds this threshold, a 1st level over current is detected. If four 1st level OC events are detected in four consecutive switching cycles, over current protection will be triggered. ● 2nd level threshold: it is an internal threshold whose value is equal to 1st level threshold multiplied by a factor 1.5. If the monitored voltage on PHASE exceeds this threshold, over current protection will be triggered immediately. When over current protection is triggered, the device turns off both LS and HS MOSFETs in a latched condition. To recover from over current protection triggered condition, VCC power supply must be cycled. 12/31 L6728 8.1 Over current protection Over current threshold setting L6728 allows to easily program a 1st level over current threshold ranging from 50 mV to 550 mV, simply by adding a resistor (ROCSET) between LGATE and GND. 2nd level threshold will be automatically set accordingly. During a short period of time (about 5 ms) following VCC rising over UVLO threshold, an internal 10 µA current (IOCSET) is sourced from LGATE pin, determining a voltage drop across ROCSET. This voltage drop will be sampled and internally held by the device as 1st level over current threshold. The OC setting procedure overall time length is about 5 ms. Connecting a ROCSET resistor between LGATE and GND, the programmed 1st level threshold will be: I OCSET ⋅ R OCSET I OCth1 = ------------------------------------------R dsON the programmed 2nd level threshold will be: I OCSET ⋅ R OCSET I OCth2 = 1.5 ⋅ -------------------------------------------R dsON ROCSET values range from 5 kΩ to 55 kΩ. In case ROCSET is not connected, the device sets the OCP thresholds to the maximum values: an internal safety clamp on LGATE is triggered as soon as LGATE voltage reaches 600 mV, setting the maximum threshold and suddenly ending OC setting phase. 13/31 Output voltage setting and protections 9 L6728 Output voltage setting and protections L6728 is capable to precisely regulate an output voltage as low as 0.8 V. In fact, the device comes with a fixed 0.8 V internal reference that guarantee the output regulated voltage to be within ±0.8 % tolerance over line and temperature variations (excluding output resistor divider tolerance, when present). Output voltage higher than 0.8 V can be easily achieved by adding a resistor ROS between FB pin and ground. Referring to Figure 1, the steady state DC output voltage will be: R FB ⎞ V OUT = V REF ⋅ ⎛ 1 + ---------⎝ R ⎠ OS where VREF is 0.8 V. L6728 monitors the voltage at VSEN pin and compares it to internal reference voltage in order to provide under voltage and over voltage protections as well as PGOOD signal. According to the level of VSEN, different actions are performed from the controller: ● PGOOD If the voltage monitored through VSEN exits from the PGOOD window limits, the device de-asserts the PGOOD signal still continuing switching and regulating. PGOOD is asserted at the end of the soft-start phase. ● Under voltage protection If the voltage at VSEN pin drops below UV threshold, the device turns off both HS and LS MOSFETs, latching the condition. Cycle VCC to recover. ● Over voltage protection If the voltage at VSEN pin rises over OV threshold (1 V typ), over voltage protection turns off HS MOSFET and turns on LS MOSFET. The LS MOSFET will be turned off as soon as VSEN goes below Vref/2 (0.4 V). The condition is latched, cycle VCC to recover. Notice that, even if the device is latched, the device still controls the LS MOSFET and can switch it on whenever VSEN rises above OV threshold. ● Feedback disconnection protection In order to provide load protection even if VSEN pin is not connected, a 100 nA bias current is always sourced from this pin. If VSEN pin is not connected, this current will permanently pull it up causing the device to detect an OV: thus LS will be latched on preventing output voltage from rising out of control. 14/31 L6728 Application details 10 Application details 10.1 Compensation network The control loop showed in Figure 5 is a voltage mode control loop. The output voltage is regulated to the internal reference (when present, offset resistor between FB node and GND can be neglected in control loop calculation). Error Amplifier output is compared to oscillator saw-tooth waveform to provide PWM signal to the driver section. PWM signal is then transferred to the switching node with VIN amplitude. This waveform is filtered by the output filter. The converter transfer function is the small signal transfer function between the output of the EA and VOUT. This function has a double pole at frequency FLC depending on the L-COUT resonance and a zero at FESR depending on the output capacitor ESR. The DC Gain of the modulator is simply the input voltage VIN divided by the peak-to-peak oscillator voltage ∆VOSC. Figure 5. PWM control loop VIN OSC ∆V OSC _ L + R V OUT COUT PWM COMPARATOR ERROR AMPLIFIER + CF ESR VREF _ RFB RF CS RS ZFB CP ZF The compensation network closes the loop joining VOUT and EA output with transfer function ideally equal to -ZF/ZFB. Compensation goal is to close the control loop assuring high DC regulation accuracy, good dynamic performances and stability. To achieve this, the overall loop needs high DC gain, high bandwidth and good phase margin. High DC gain is achieved giving an integrator shape to compensation network transfer function. Loop bandwidth (F0dB) can be fixed choosing the right RF/RFB ratio, however, for stability, it should not exceed FSW/2π. To achieve a good phase margin, the control loop gain has to cross 0 dB axis with -20 dB/decade slope. As an example, Figure 6 shows an asymptotic bode plot of a type III compensation. 15/31 Application details Figure 6. L6728 Example of type III compensation Gain [dB] open loop EA gain FZ1 FZ2 FP1 FP2 closed loop gain compensation gain 20log (RF/RFB) open loop converter gain 20log (VIN/∆VOSC ) 0dB F0dB FLC ● ● Log (Freq) FESR Open loop converter singularities: a) 1 F LC = --------------------------------2π L ⋅ C OUT b) 1 F ESR = ------------------------------------------2π ⋅ C OUT ⋅ ESR Compensation network singularities frequencies: a) 1 F Z1 = -----------------------------2π ⋅ R F ⋅ C F b) 1 F Z2 = ----------------------------------------------------2π ⋅ ( R FB + R S ) ⋅ C S c) 1 F P1 = -------------------------------------------------CF ⋅ CP 2π ⋅ R F ⋅ ⎛⎝ ---------------------⎞⎠ CF + CP d) 1 F P2 = -----------------------------2π ⋅ R S ⋅ C S To place the poles and zeroes of the compensation network, the following suggestions may be followed: a) Set the gain RF/RFB in order to obtain the desired closed loop regulator bandwidth according to the approximated formula (suggested values for RFB are in the range of some kΩ): F 0dB ∆V OSC RF = ------------ ⋅ ---------------------------F LC V IN R FB 16/31 L6728 Application details b) Place FZ1 below FLC (typically 0.5*FLC): 1 C F = ----------------------------π ⋅ R F ⋅ F LC c) Place FP1 at FESR: CF C P = ---------------------------------------------------------2π ⋅ R F ⋅ C F ⋅ F ESR – 1 d) Place FZ2 at FLC and FP2 at half of the switching frequency: R FB R S = -------------------------F SW ------------------ – 1 2 ⋅ F LC 1 C S = -----------------------------π ⋅ R S ⋅ F SW 10.2 e) Check that compensation network gain is lower than open loop EA gain before F0dB; f) Check phase margin obtained (it should be greater than 45°) and repeat if necessary. Layout guidelines L6728 provides control functions and high current integrated drivers to implement highcurrent step-down DC-DC converters. In this kind of application, a good layout is very important. The first priority when placing components for these applications has to be reserved to the power section, minimizing the length of each connection and loop as much as possible. To minimize noise and voltage spikes (EMI and losses) power connections (highlighted in Figure 7) must be a part of a power plane and anyway realized by wide and thick copper traces: loop must be anyway minimized. The critical components, i.e. the power MOSFETs, must be close one to the other. The use of multi-layer printed circuit board is recommended. The input capacitance (CIN), or at least a portion of the total capacitance needed, has to be placed close to the power section in order to eliminate the stray inductance generated by the copper traces. Low ESR and ESL capacitors are preferred, MLCC are suggested to be connected near the HS drain. Use proper VIAs number when power traces have to move between different planes on the PCB in order to reduce both parasitic resistance and inductance. Moreover, reproducing the same high-current trace on more than one PCB layer will reduce the parasitic resistance associated to that connection. Connect output bulk capacitors (COUT) as near as possible to the load, minimizing parasitic inductance and resistance associated to the copper trace, also adding extra decoupling capacitors along the way to the load when this results in being far from the bulk capacitors bank. 17/31 Application details Figure 7. L6728 Power connections (heavy lines) VIN CIN UGATE PHASE L L6728 COUT LGATE LOAD GND Gate traces and phase trace must be sized according to the driver RMS current delivered to the power MOSFET. The device robustness allows managing applications with the power section far from the controller without losing performances. Anyway, when possible, it is recommended to minimize the distance between controller and power section. Small signal components and connections to critical nodes of the application, as well as bypass capacitors for the device supply, are also important. Locate bypass capacitor (VCC and Bootstrap capacitor) and feedback compensation components as close to the device as practical. For over current programmability, place ROCSET close to the device and avoid leakage current paths on LGATE / OC pin, since the internal current source is only 10 µA. Systems that do not use Schottky diode in parallel to the low-side MOSFET might show big negative spikes on the phase pin. This spike must be limited within the absolute maximum ratings (for example, adding a gate resistor in series to HS MOSFET gate), as well as the positive spike, but has an additional consequence: it causes the bootstrap capacitor to be over-charged. This extra-charge can cause, in the worst case condition of maximum input voltage and during particular transients, that boot-to-phase voltage overcomes the absolute maximum ratings also causing device failures. It is then suggested in this cases to limit this extra-charge by adding a small resistor in series to the bootstrap diode. Figure 8. Drivers turn-on and turn-off paths LS DRIVER LS MOSFET HS DRIVER VCC HS MOSFET BOOT CGD RGATE CGD RINT RGATE LGATE UGATE CGS GND 18/31 RINT CDS CGS PHASE CDS L6728 Application information 11 Application information 11.1 Inductor design The inductance value is defined by a compromise between the dynamic response time, the efficiency, the cost and the size. The inductor has to be calculated to maintain the ripple current (∆IL) between 20 % and 30 % of the maximum output current (typ). The inductance value can be calculated with the following relationship: V IN – V OUT V OUT L = ------------------------------ ⋅ -------------F SW ⋅ ∆I L V IN Where FSW is the switching frequency, VIN is the input voltage and VOUT is the output voltage. Figure 9 shows the ripple current vs. the output voltage for different values of the inductor, with VIN = 5 V and VIN = 12 V. Increasing the value of the inductance reduces the current ripple but, at the same time, increases the converter response time to a dynamic load change. The response time is the time required by the inductor to change its current from initial to final value. Until the inductor has not finished its charging time, the output current is supplied by the output capacitors. Minimizing the response time can minimize the output capacitance required. If the compensation network is well designed, during a load variation the device is able to set a duty cycle value very different (0 % or 80 %) from steady state one. When this condition is reached, the response time is limited by the time required to change the inductor current. Figure 9. Inductor current ripple vs output voltage 19/31 Application information 11.2 L6728 Output capacitor(s) The output capacitors are basic components to define the ripple voltage across the output and for the fast transient response of the power supply. They depend on the output voltage ripple requirements, as well as any output voltage deviation requirement during a load transient. During steady-state conditions, the output voltage ripple is influenced by both the ESR and capacitive value of the output capacitors as follow: ∆V OUT_ESR = ∆I L ⋅ ESR 1 ∆V OUT_C = ∆I L ⋅ --------------------------------------8 ⋅ C OUT ⋅ F SW Where ∆IL is the inductor current ripple. In particular, the expression that defines ∆VOUT_C takes in consideration the output capacitor charge and discharge as a consequence of the inductor current ripple. During a load variation, the output capacitors supplies the current to the load or absorb the current stored into the inductor until the converter reacts. In fact, even if the controller recognizes immediately the load transient and sets the duty cycle at 80 % or 0 %, the current slope is limited by the inductor value. The output voltage has a drop that also in this case depends on the ESR and capactive charge/discharge as follow: ∆V OUT_ESR = ∆I OUT ⋅ ESR L ⋅ ∆I OUT ∆V OUT_C = ∆I OUT ⋅ -------------------------------------2 ⋅ C OUT ⋅ ∆V L Where ∆VL is the voltage applied to the inductor during the transient response ( D MAX ⋅ V IN – V OUT for the load appliance or VOUT for the load removal). MLCC capacitors have typically low ESR to minimize the ripple but also have low capacitance that do not minimize the voltage deviation during dynamic load variations. On the contrary, electrolytic capacitors have big capacitance to minimize voltage deviation during load transients while they does not show the same ESR values of the MLCC resulting then in higher ripple voltages. For these reasons, a mix between electrolytic and MLCC capacitor is suggeted to minimize ripple as well as reducing voltage deviation in dynamic mode. 11.3 Input capacitors The input capacitor bank is designed considering mainly the input rms current that depends on the output deliverable current (IOUT) and the duty-cycle (D) for the regulation as follow: I rms = I OUT ⋅ D ⋅ ( 1 – D ) The equation reaches its maximum value, IOUT/2, with D = 0.5. The losses depends on the input capacitor ESR and, in worst case, are: P = ESR ⋅ ( I OUT ⁄ 2 ) 20/31 2 L6728 12 20 A demonstration board 20 A demonstration board L6728 demonstration board realizes in a four-layer PCB a step-down DC/DC converter and shows the operation of the device in a general purpose application. The input voltage can range from 5 V to 12 V buses and the output voltage is fixed at 1.25 V. The application can deliver an output current up to 30 A. The switching frequency is 300 kHz. Figure 10. 20 A demonstration board (left) and components placement (right) Figure 11. L6728 - 20 A demonstration board top (left) and bottom (right) layers Figure 12. L6728 - 20 A demonstration board inner layers 21/31 20 A demonstration board Figure 13. 20 A demonstration board schematic 22/31 L6728 L6728 20 A demonstration board Table 6. 20 A demonstration board - bill of material Qty Reference Description Package Capacitors 2 C1, C2 Electrolytic capacitor 1800 µF 16 V Nippon chemi-con KZJ or KZG 1 C10 MLCC, 100 nF, 16V, X7R SMD0603 3 C11 to C13 MLCC, 4.7 µF, 16V, X5R Murata GRM31CR61C475MA01 SMD1206 2 C14, C38 MLCC, 1 µF, 16V, X7R SMD0805 2 C15, C19 MLCC, 10 µF, 6.3 V, X7R Murata GRM31CR70J106KA01L SMD1206 2 C18, C20 Electrolytic capacitor 2200 µF 6.3 V Nippon chemi-con KZJ or KZG 1 C23 MLCC, 6.8 nF, X7R 1 C24 MLCC, 33 nF, X7R 1 C35 MLCC, 68 pF, X7R Radial 10 x 25 mm Radial 10 x 20 mm SMD0603 Resistors 4 R1, R2, R20, R17 Resistor, 3R3, 1/16W, 1 % 4 R3, R5, R11, R16 Resistor, 0R, 1/8W, 1 % 1 R4 Resistor, 1R8, 1/8W, 1 % 2 R6, R9 Resistor, 2K2, 1/16W, 1 % 2 R8, R13 Resistor, 3K9, 1/16W, 1 % 1 R7 Resistor, 18K, 1/16W, 1 % 1 R19 Resistor, 22K, 1/16W, 1 % 1 R18 Resistor, 20K, 1/16W, 1 % L1 Inductor, 1.25 µH, T60-18, 6 turns Easymagnet AP106019006P-1R1M SMD0603 SMD0805 SMD0603 Inductor 1 na Active components 1 D1 Diode, 1N4148 or BAT54 1 Q5 STD70N02L 1 Q7 STD95NH02LT4 1 U1 Controller, L6728 SOT23 DPACK DFN10, 3x3 mm 23/31 20 A demonstration board 12.1 Board description 12.1.1 Power input (Vin) L6728 This is the input voltage for the power conversion. The High-Side drain is connected to this input. This voltage can range from 1.5 V to 12 V bus. If the voltage is between 4.5 V and 12 V it can supply also the device (through the Vcc pin) and in this case the R16 (0 Ω) resistor must be present. 12.1.2 Output (Vout) The output voltage is fixed at 1.25 V but it can be changed by replacing the resistors R8 (sense partition lower resistor ) and R13 (feedback partition lower resistor). R18 allows to adjust OCP threshold. 12.1.3 Signal input (Vcc) Using the input voltage Vin to supply the controller no power is required at this input. However the controller can be supplied separately from the power stage through the Vcc input (4.5-12 V) and, in this case, the R16 (0 Ω) resistor must be unsoldered. 12.1.4 Test points Several test points are provided to have easy access at all important signal characterizing the device: 12.1.5 – COMP: the output of the error amplifier; – FB: the inverting input of the error amplifier; – PGOOD: signaling the regular functioning (active high); – VGDHS: the bootstrap diode anode; – PHASE: Phase node; – LGATE: Low-side gate pin of the device; – HGATE: High-side gate pin of the device. Board characterization Figure 14. 20 A demonstration board efficiency 24/31 L6728 13 5 A demonstration board 5 A demonstration board L6728 demonstration board realizes in a two-layer PCB a step-down DC/DC converter and shows the operation of the device in a general-purpose low-current application. The input voltage can range from 5 V to 12 V buses and the output voltage is fixed at 1.25 V. The application can deliver an output current in excess of 5 A. The switching frequency is 300 kHz. Figure 15. L6728 - 5 A demonstration board (left) and components placement (right) Figure 16. L6728 - 5 A demonstration board top (left) and bottom (right) layers 25/31 ᤡ 0 5 GND LGATE UGATE PHASE BOOT ᤢ 1uF 220pF 68nF 4.7k 0 R13 3.9k R9 0 R8 3.9k R14 VSEN 15 2.2k 6.8nF C36 R1 Vsen VCC 3.3 LGATE LGATE 2.2k R6 R17 3.3 3.3 R5 PHASE R3 C10 100nF BOOT 0 0 HSG1 4 3 Q5a 5 /6 HSD VIN_POWER LSG1 2 1 0 Q5b 7 /8 0 L2 2.2uH C23 6.8nF R4 1.8 2 1 0 ᤡ C12 10uF ᤡ 330uF 0 22uF C39 OUT 0 NC C40 ᤢ C30 OUT NC 0 ᤡ ᤢ 0 C29 OUT ᤡ 0 NC C18 OUT ᤢ C51 10uF ᤢ W Q L U S W R R I O D X G C35 C24 7 VCC_PIN FB COMP 8 6 VSEN 9 10 R19 22k R2 PHASE PIN PHASE UGATE BAT54 V U R W L F D S D F F L P D U H F R7 FB U H O O N UR U RW Q ZR WF H 1 H QK W R U LD W DH VQ Q HH SF PD O RS & COMP VCC COMP FB VSEN PGOOD C14 L6728 PGOOD 0 VCC_PIN C38 1uF D1 V U R W L F D S D F P X O D W Q D 7 R18 10k 4 3 2 1 U1 GND VCC R16 0 U R W L F D S D F F L W \ O R U W F H O ( LGATE UGATE PHASE PIN GND GNDIN1 / / + 1 ' 6 7 6 W H I V R 0 O D X ' BOOT 0 GNDCC VCC VCC GND 0 GNDIN_POWER VIN1 V U R W L F D S D F F L P D U H F W Q L U S W R R I O D X G COMP 26/31 W Q L U S W R R I O D X G FB V R P 6 + U D H Q H F D O S OUT VIN_POWER VOUT 0 GNDOUT1 GNDOUT VOUT1 5 A demonstration board L6728 Figure 17. 5 A demonstration board schematic L6728 5 A demonstration board Table 7. 5 A demonstration board - bill of material Qty Reference Description Package Capacitors 2 C12, C51 MLCC, 10 µF, 25 V, X5R Murata GRM31CR61E106KA12 SMD1206 1 C10 MLCC, 100 nF, 16 V, X7R SMD0603 2 C14, C38 MLCC, 1 µF, 16 V, X7R SMD0805 1 C39 MLCC, 22 µF, 6.3 V, X5R Murata GRM31CR60J226ME19L SMD1206 1 C30 330 µF, 6.3 V, 9 mΩ Sanyo 6TPF330M9L SMD7343 2 C23, C36 MLCC, 6.8 nF, X7R 1 C24 MLCC, 68 nF, X7R 1 C35 MLCC, 220 pF, X7R 3 R1, R2, R17 Resistor, 3R3, 1/16 W, 1 % SMD0603 3 R3, R5, R16 Resistor, 0R, 1/16 W, 1 % SMD0603 1 R4 Resistor, 1R8, 1/8 W, 1 % SMD0805 1 R14 Resistor, 15R, 1/16 W, 1 % SMD0603 2 R6, R9 Resistor, 2K2, 1/16 W, 1 % 2 R8, R13 Resistor, 3K9, 1/16 W, 1 % 1 R7 Resistor, 4K7, 1/16 W, 1 % 1 R19 Resistor, 22K, 1/16 W, 1 % 1 R18 Resistor, 10K, 1/16 W, 1 % L1 Inductor, 2.2 µH, WURTH 744324220LF SMD0603 Resistors SMD0603 Inductor 1 na Active Components 1 D1 Diode, BAT54 1 Q5 STS9D8NH3LL 1 U1 Controller, L6728 13.1 Board description 13.1.1 Power input (Vin) SOT23 SO8 DFN10, 3x3 mm This is the input voltage for the power conversion. The high-side drain is connected to this input. This voltage can range from 1.5 V to 12 V bus. 27/31 5 A demonstration board L6728 If the voltage is between 4.5 V and 12 V it can supply also the device (through the Vcc pin) and in this case the R16 (0Ω) resistor must be present. 13.1.2 Output (Vout) The output voltage is fixed at 1.25 V but it can be changed by replacing the resistors R8 (sense partition lower resistor ) and R13 (feedback partition lower resistor). R18 allows to adjust OCP threshold. 13.1.3 Signal input (Vcc) Using the input voltage Vin to supply the controller no power is required at this input. However the controller can be supplied separately from the power stage through the Vcc input (4.5-12 V) and, in this case, the R16 (0 Ω) resistor must be unsoldered. 13.1.4 Test points Several test points are provided to have easy access at all important signal characterizing the device: 13.1.5 – COMP: the output of the error amplifier; – FB: the inverting input of the error amplifier; – PGOOD: signaling the regular functioning (active high); – VGDHS: the bootstrap diode anode; – PHASE: Phase node; – LGATE: Low-side gate pin of the device; – HGATE: High-side gate pin of the device. Board characterization Figure 18. 5 A demonstration board efficiency 28/31 L6728 Package mechanical data In order to meet environmental requirements, ST offers these devices in ECOPACK® packages. These packages have a lead-free second level interconnect. The category of second level interconnect is marked on the package and on the inner box label, in compliance with JEDEC Standard JESD97. The maximum ratings related to soldering conditions are also marked on the inner box label. ECOPACK is an ST trademark. ECOPACK specifications are available at: www.st.com Table 8. DFN10 mechanical data mm mils Dim. Min Typ Max Min Typ Max 0.80 0.90 1.00 31.5 35.4 39.4 A1 0.02 0.05 0.8 2.0 A2 0.70 27.6 A3 0.20 7.9 A b 0.18 D D2 2.21 7.1 9.1 2.26 1.49 1.64 2.31 87.0 89.0 0.4 90.9 118.1 1.74 58.7 64.6 0.50 0.3 11.8 118.1 3.00 e L 0.30 3.00 E E2 0.23 68.5 19.7 0.5 11.8 15.7 M 0.75 29.5 m 0.25 9.8 19.7 M Figure 19. Package dimensions m 14 Package mechanical data 29/31 Revision history 15 L6728 Revision history Table 9. 30/31 Document revision history Date Revision Changes 29-Jun-2007 1 Initial release 17-Sep-2007 2 Updated TJ value in Table 3: Thermal data on page 6 05-Jun-2008 3 Added Figure 11 on page 21 Updated Section 14 on page 29, coverpage, Table 6 on page 23, Figure 17 on page 26, Table 7 on page 27 L6728 Please Read Carefully: Information in this document is provided solely in connection with ST products. STMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, modifications or improvements, to this document, and the products and services described herein at any time, without notice. All ST products are sold pursuant to ST’s terms and conditions of sale. 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