A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator FEATURES AND BENEFITS DESCRIPTION • • • • • • • • The A8654 is a high output current synchronous buck regulator that integrates low RDSON high-side and low-side N-channel MOSFETs. The A8654 incorporates PWM current-mode control to provide simple compensation, excellent loop stability and fast transient response. The A8654 uses external compensation to accommodate a wide range of power components to achieve both excellent loop stability and desirable transient response. The A8654 regulates nominal input voltages from 4 to 36 V and remains operational when VIN drops as low as 2.6 V. When the input voltage approaches the output voltage, the duty cycle is maximized to maintain the output voltage. The A8654 is able to provide 3 A steady-state load current. • • • • • • Automotive AEC-Q100 qualified Operating voltage range: 4 to 36 V UVLO STOP threshold: 2.6 VTYP Maximized duty cycle for low-dropout operation Withstands surge voltages up to 40 V Capable of 3 A steady-state output current Integrated high-side and low-side switching MOSFETs Adjustable switching frequency (fSW): 100 kHz to 2.2 MHz Synchronization capability to external clock: 100 kHz to 2.2 MHz Frequency dithering for lower EMI signature External adjustable compensation network Soft-start time externally set via the SS pin Pre-bias startup compatible Active-low, power-on reset (NPOR) output The A8654 features externally set soft-start time, external compensation network, an EN input to enable VOUT, a SYNC/FSET input to synchronize or set the PWM switching Continued on next page... Continued on next page... APPLICATIONS PACKAGES: 16-Pin eTSSOP (LP) with exposed thermal pad • Automotive Infotainment • Systems □□ Audio, Video Navigation Systems □□ Rear Seat Media Display □□ Instrument Clusters □□ Telematics • Not to scale VIN CIN 2 × 4.7 µF BOOT VIN CBOOT 100 nF GND LO SW CO EN SYNC/FSET A8654 RFSET SS RPU 10 kΩ NPOR CSS 22 nF COMP RFB1 CP RZ CZ FB RFB2 Typical Application Diagram 1 A8654-DS, Rev. 2 Advanced Driver Assistance Systems □□ RADAR, LIDAR, mmWave systems □□ Vision and Detection System Industrial □□ General 24 V / 36 V applications Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 FEATURES AND BENEFITS (continued) • Overvoltage protection, pulse-by-pulse current limit, hiccup mode short-circuit and thermal protections • Open-circuit and adjacent pin short-circuit tolerant • Short-to-ground tolerant at every pin • Stable with ceramic output capacitors DESCRIPTION (continued) frequency, and a NPOR output validated by the output voltage. Protection features include VIN undervoltage lockout (UVLO), pulse-by-pulse overcurrent protection, hiccup mode short-circuit protection, overvoltage protection, and thermal shutdown. A8654 provides open-circuit, adjacent pin short-circuit and short-to-ground protection at every pin to satisfy the most demanding automotive and nonautomotive applications. The maximum junction temperature is 150°C. The A8654 device is available in a 16-pin eTSSOP package with exposed pads for enhanced thermal dissipation. It is lead (Pb) free, with 100% mattetin leadframe plating. SELECTION GUIDE Part Number A8654KLPTR-T Packing Package 4000 pieces per 13-inch reel 4.4 mm × 5 mm, 1.2 mm nominal height 16-pin eTSSOP with exposed thermal pad Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 2 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 SPECIFICATIONS ABSOLUTE MAXIMUM RATINGS1 Characteristic Symbol Notes Rating VIN, EN, SS SW to GND 2 BOOT Pin Above SW Pin VSW VBOOT Continuous VIN ≤ 36 V, t < 50 ns Storage Temperature Range V –0.3 to VIN + 0.3 V –1.0 to VIN + 2.0 V Continuous VSW – 0.3 to VSW + 5.5 V < 1 ms VSW – 0.3 to VSW + 7.0 V –0.3 to 5.5 V All other pins Maximum Junction Temperature Unit –0.3 to 40 TJ(max) 150 °C Tstg –55 to 150 °C 1 Stresses beyond those listed in this table may cause permanent damage to the device. The absolute maximum ratings are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the Electrical Characteristics table is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability 2 SW has internal clamp diodes to GND and VIN. Applications that forward bias these diodes should take care not to exceed the IC package power dissipation limits. THERMAL CHARACTERISTICS Characteristic Package Thermal Resistance 3 Additional Symbol RθJA Test Conditions 3 LP Package, 4-layer PCB based on JEDEC standard Value Unit 34 °C/W thermal information available on the Allegro website. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 3 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 PINOUT DIAGRAM AND TERMINAL LIST TABLE EN 1 16 BOOT VIN 2 15 SW SS 3 14 PGND TSTGND1 4 13 PGND FB 5 TSTGND2 6 11 TSTGND3 SGND 7 10 NPOR COMP 8 9 PAD 12 TSTGND4 SYNC/FSET Package LP, 16-Pin eTSSOP Pinout Diagram Terminal List Table Symbol Number Function EN 1 Enable input. This pin is used to turn the converter on or off; set this pin high to turn the converter on or set this pin low to turn the converter off. May be connected to VIN. VIN 2 Power input for the control circuits and the drain of the internal high-side N-channel MOSFET. A high quality ceramic capacitor should be placed very close to this pin. SS 3 Soft-Start pin. Connect a capacitor (CSS) from this pin to GND to set the soft-start time. This capacitor also determines the hiccup period during overcurrent. FB 5 Feedback (negative) input to the error amplifier. Connect a resistor divider from the converter output node (VOUT) to this pin to program the output voltage. SGND 7 Signal (quiet) ground. COMP 8 Output of the error amplifier and compensation node for the control loop. Connect a series RC network from this pin to GND for loop compensation. SYNC/FSET 9 Frequency setting and synchronization pin. A resistor, RFSET, from this pin to GND sets the PWM switching frequency. NPOR 10 Active-low, power-on reset output signal. This pin is an open-drain output that transitions from low to high impedance after the output has maintained regulation for tD,NPOR. TSTGND1-4 4, 6, 11, 12 PGND 13, 14 SW 15 The source of the high-side N-channel MOSFET. The output inductor (LO) should be connected to this pin. LO should be placed as close as possible to this pin and connected with relatively wide traces. BOOT 16 High-side gate drive boost input. Connect a 100 nF ceramic capacitor from BOOT to SW PAD – Exposed pad of the package providing enhanced thermal dissipation. This pad must be connected to the ground plane(s) of the PCB with at least 6 vias, directly in the pad. Internal test pins, not for use. Should be connected to ground but do not use as main power ground. Power ground. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 4 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 VIN BOOT REG VIN VREF Regulator VREG BOOT UVLO Current Sense Amp EN TSD OCP 500 nA EN Protection & Fault OVP SYNC/FSET OSC SW Adj 5 µs CLK 80 mΩ 110% VREF FB PWM Control Logic PWM COMP Error Amp VREG 55 mΩ VREF 800 mV Σ COMP Slope Comp PGND Ramp Offset 20 µA 5 µA HICCUP LOGIC 400 mV 2 kΩ FAULT SS NPOR UV SGND OV Functional Block Diagram Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 5 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 ELECTRICAL CHARACTERISTICS: Valid at 4.0 V ≤ VIN ≤ 36 V; TA = 25°C; ● indicates specifications guaranteed ‒40°C ≤ TA = TJ ≤ 150°C, unless noted otherwise. Characteristics Symbol Test Conditions Min. Typ. Max. Unit 4.0 – 36.0 V INPUT VOLTAGE SPECIFICATIONS Operating Input Voltage Range 2 VIN ● UVLO Start Threshold VUVLO(START) VIN rising – 3.4 3.7 V UVLO Stop Threshold VUVLO(STOP) VIN falling – 2.6 2.9 V UVLO Hysteresis VUVLO(HYS) – 800 – mV – 3.0 6.5 mA VIN = 12 V, VEN ≤ 0.4 V, –40˚C < TA = TJ < 85˚C – 1 240 µA VIN = 12 V, VEN ≤ 0.4 V, TA = TJ = 125˚C – 40 900 µA INPUT CURRENTS Input Quiescent Current 1 Input Sleep Supply Current 1 IQ IQ(SLEEP) VEN = 5 V, VFB = 1.0 V, no PWM switching ● VOLTAGE REGULATION Feedback Voltage Accuracy 3 Output Dropout Voltage 3 VFB VO(PWM) VFB = VCOMP, -40˚C < TA = TJ < 125˚C 792 800 808 mV VFB = VCOMP ● 788 800 812 mV VIN = 5.9 V, IO = 3 A, fSW = 500 kHz ● 4.9 – – V VIN = 7.5 V, IO = 3 A, fSW = 2 MHz ● 4.9 – – V ERROR AMPLIFIER Feedback Input Bias Current 1 Open Loop Voltage Gain IFB AVOL Transconductance gm Output Current IEA –100 – –8 nA VCOMP = 1.2 V – 65 – dB 400 mV < VFB 550 750 950 0 V < VFB < 400 mV 275 375 475 – ±75 – VCOMP = 1.2 V µA/V µA INTERNAL MOSFET PARAMETERS High-Side MOSFET On Resistance 3 SW Node Rising Slew Rate RDSON(HS) dV/dt TA = 25˚C, IDS = 100 mA – 80 – mΩ 12 V < VIN < 16 V – 0.75 – V/ns –10 0 10 µA SW Leakage 1 ISW(LEAK) VEN ≤ 0.4 V, VSW = 5 V, VIN = 12 V, TJ = 25˚C Low-Side MOSFET On Resistance 3 RDSON(LS) TA = 25˚C, IDS = 100 mA – 55 – mΩ RFSET = 261 kΩ – 100 – kHz RFSET = 61.9 kΩ 375 415 457 kHz RFSET = 10.5 kΩ – 2.0 – MHz OSCILLATOR PWM Switching Frequency fSW PWM Frequency Dithering fDITHER No Dithering with FSET Synchronization – ±13 – % Minimum Controllable On-Time tON(MIN) VIN = 12 V, IOUT = 1 A – 95 135 ns Minimum Switch Off-Time tOFF(MIN) VIN = 12 V, IOUT = 1 A – 100 135 ns Continued on the next page… Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 6 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 ELECTRICAL CHARACTERISTICS (continued): Valid at 4.0 V ≤ VIN ≤ 36 V; TA = 25°C; ● indicates specifications guaranteed ‒40°C ≤ TA = TJ ≤ 150°C, unless noted otherwise. Characteristics Symbol Test Conditions Min. Typ. Max. Unit FSET SYNCHRONIZATION TIMING Synchronization Frequency Range fSW_MULT 100 – 2200 kHz Synchronization Input Off-Time tSYNC_OFF 0.2 – 1.3 µs tr(SYNC) – 10 15 ns tf(SYNC) – 10 15 ns Synchronization Input Rise Time 3 Synchronization Input Fall Time 3 Synchronization Rising Threshold VSYNC(HI) VSYNC rising – – 2.0 V Synchronization Falling Threshold VSYNC(LO) VSYNC falling 0.5 – 0.7 V IPK_LIM(MINON) tON = tON(MIN) 4.1 4.7 5.3 A IPK_LIM(MINOFF) tON = 1/fSW – tOFF(MIN), no sync 3.0 3.9 4.8 A – 7.3 – A/V RFSET = 261 kΩ, 100 kHz – 0.056 – A/µs RFSET = 61.9 kΩ, 415 kHz CURRENT LOOP Peak Inductor (Pulse-by-Pulse) Current Limit COMP to SW Current Gain Slope Compensation gmPOWER SE 0.09 0.24 0.43 A/µs RFSET = 10.5 kΩ, 2 MHz – 1.3 – A/µs VSS falling due to RSS(FLT) – 200 275 mV SOFT-START SS FAULT/HICCUP Reset Voltage VSS(RST) SS Maximum Charge Voltage VSS(MAX) SS Startup (Source) Current 1 ISS(SU) HICCUP = FAULT = 0 SS Hiccup (Sink) Current 1 ISS(HIC) SS Pull-Down Resistance RSS(FLT) SS Switching Frequency fSS – 3.3 – V –30 –20 –10 µA HICCUP = 1 1 2.2 5 µA FAULT = 1 or EN = 0 – 2 – kΩ 0 V < VFB < 200 mV – fSW/4 – – 200 mV < VFB < 400 mV – fSW/2 – – 400 mV < VFB – fSW – – VHIC(EN) VSS rising – 2.3 – V Hiccup, OCP Count OCPLIM VSS > 2.3 V, OCP pulses – 240 – counts Hiccup, BOOT Shorted Count BOOTUV – 64 – counts BOOTOPEN – 7 – counts 840 880 920 mV – 10 – mV HICCUP MODE Hiccup OCP Enable Threshold Hiccup, BOOT Open Count NPOR OUTPUT VOUT OV Threshold VOUT(OV) VOUT OV Hysteresis VOUT(OV,HYS) VOUT UV Threshold VOUT(UV) VOUT UV Hysteresis VOUT(UV,HYS) NPOR Rising Delay td(NPOR) NPOR Low Output Votlage NPOR Leakage 1 VFB rising VFB falling, relative to VOUT(OV) VFB falling 715 740 760 mV VFB rising, relative to VOUT(UV) – 10 – mV VFB rising only – 2500 – PWM Cycles VOL(NPOR) IPOR = 5 mA – 185 400 mV INPOR(LEAK) VPOR = 5.5 V – – 5 µA Continued on the next page… Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 7 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 ELECTRICAL CHARACTERISTICS (continued): Valid at 4.0 V ≤ VIN ≤ 36 V; TA = 25°C; ● indicates specifications guaranteed ‒40°C ≤ TA = TJ ≤ 150°C, unless noted otherwise. Characteristics Symbol Test Conditions Min. Typ. Max. Unit 155 170 185 °C – 20 – °C V THERMAL PROTECTION TSD Rising Threshold TSD Hysteresis 3 TSD PWM stops immediately and COMP is pulled low and SS is reset TSDHYS EN INPUT THRESHOLDS EN High Threshold VEN(H) EN rising – 1.41 2.0 EN Low Threshold VEN(L) EN falling 0.7 1.36 – V EN Delay EN Input Bias Current 1 td(EN) IEN_BIAS EN transitioning low, VOUT < 25% – 60 – PWM cycles EN = 5 V – 500 – nA 1 For input and output current specifications, negative current is defined as coming out of (sourcing) the specified device pin or node. limited depending on input voltage, output voltage, duty cycle, regulator load currents, PCB layout, and airflow. 3 Ensured by design and characterization, not production tested. 2 Thermally Continued on the next page… Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 8 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 TYPICAL PERFORMANCE CHARACTERISTICS 4.85 815 4.80 4.75 805 IPK_LIM(MINON) (A) Reference Voltage, VREF (mV) 810 800 4.70 4.65 4.60 795 4.55 790 4.50 4.45 785 -50 -25 0 25 50 75 100 125 150 -50 175 -25 0 25 50 75 100 125 150 175 Temperature (ºC) Temperature (ºC) Pulse-by-pulse Current Limit at tON(MIN) (IPK_LIM(MINON)) versus Temperature Reference Voltage versus Temperature 1.6 3.50 EN Rising Threshold 3.25 EN Falling Threshold 1.4 START, UVLOSTART EN Thresholds (V) VIN UVLO Thresholds (V) 1.5 STOP, UVLOSTART 3.00 2.75 1.3 1.2 1.1 1.0 0.9 2.50 -50 -25 0 25 50 75 100 125 150 -50 175 -25 0 25 VIN UVLO START and STOP Thresholds versus Temperature 75 100 125 150 175 EN Rising and Falling Thresholds versus Temperature 65.0 925 900 62.5 875 60.0 850 825 NPOR Overvoltage 800 NPOR Undervoltage AVOL (dB) NPOR OV & UV Thresholds at FB (mV) 50 Temperature (ºC) Temperature (ºC) 57.5 55.0 775 750 52.5 725 50.0 700 -50 -25 0 25 50 75 100 125 150 Temperature (ºC) NPOR Overvoltage and Undervoltage Thresholds at FB versus Temperature 175 -50 -25 0 25 50 75 100 125 150 175 Temperature (ºC) Open Loop Voltage Gain (AVOL) of Error Amplifier versus Temperature Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 9 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 900 5.5 VFB > 400 mV 0 < VFB < 400 mV 5.0 Input Quiescent Current (mA) Transconductance (µA/V) 800 700 600 500 400 4.5 4.0 3.5 3.0 300 200 2.5 -50 0 -25 25 75 50 125 100 150 175 -50 0 -25 25 Temperature (ºC) Error Amplifier Transconductance versus Temperature 100 125 150 175 Quiescent Current IQ versus Temperature 5.00 96 4.50 94 4.00 92 3.50 90 Efficiency (%) VOUT (V) 75 50 Temperature (ºC) 3.00 2.50 2.00 1.50 88 86 84 VIN = 8 V 82 VIN = 12 V 1.00 80 0.50 78 VOUT vs. VIN VIN = 16 V 0 0.5 1.5 1.0 0.00 2.0 2.5 3.0 Load (A) 2.5 3.0 3.5 4.5 4.0 5.0 5.5 6.0 VIN (V) Low VIN Dropout Operation at 5 Ω Load Efficiency versus Output Current for Typical Designs (500 kHz in Table 3) 5.1 V 5.1 V VOUT VOUT 5.0 V 5.0 V 4.9 V 4.9 V 25 mA/µs 1 A/div 1 A/div IOUT 25 mA/µs IOUT 100 µs/div 100 µs/div Transient Response 0 A to 1 A Load Step Transient Response 1 A to 2 A Load Step (Typical Design - 500 kHz in Table 3) (Typical Design - 500 kHz in Table 3) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 10 A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator FUNCTIONAL DESCRIPTION Overview The A8654 is a synchronous PWM buck regulator that integrates low RDSON high-side and low-side N-channel MOSFETs. It is designed to remain operational when input voltage falls as low as 2.6 V. The A8654 employs peak current-mode control to provide superior line and load regulation, pulse-by-pulse current limit, fast transient response, and simple compensation. The features of the A8654 include an internal precision reference, an adjustable switching frequency, a transconductance error amplifier, an enable input, integrated top and bottom switching MOSFETs, adjustable soft-start time, pre-bias startup, and an NPOR output. Protection features of A8654 include VIN undervoltage lockout, pulse-by-pulse overcurrent protection, BOOT overvoltage and undervoltage protection, hiccup mode shortcircuit protection, overvoltage protection, and thermal shutdown. In addition, the A8654 provides open-circuit, adjacent pin shortcircuit, and pin-to-ground short-circuit protection. Reference Voltage duty-cycle, and rise/fall time requirements shown in the Electrical Characteristics table in this datasheet. Transconductance Error Amplifier The transconductance error amplifier’s primary function is to control the regulator’s output voltage. The error amplifier is a three-terminal input device with two positive inputs and one negative input, as shown in Figure 1. The negative input is simply connected to the FB pin and is used to sense the feedback voltage for regulation. The error amplifier performs an “analog OR” selection between its positive inputs, operating according to the positive input with the lowest potential. The two positive inputs are used for soft-start and steady-state regulation. The error amplifier regulates to the soft-start pin voltage minus 400 mV during startup or the A8654’s internal reference (VREF) during normal operation. 400 mV SS The A8654 incorporates an internal precision reference that allows output voltages as low as 0.8 V. The accuracy of the internal reference is ±1% from –40°C to 125°C and ±1.5% across from –40°C to 150°C. The output voltage of the regulator is programmed with a resistor divider between VOUT and the FB pin of the A8654. Error Amp COMP VREF 800 mV Oscillator/Switching Frequency and Synchronization The PWM switching frequency of the A8654 is adjustable from 100 kHz to 2.2 MHz and has an accuracy of about ±10% over the operating temperature range. Connecting a resistor from the FSET/SYNC pin to GND, as shown in the Applications Schematic, sets the switching frequency. An FSET resistor with ±1% tolerance is recommended. A graph of switching frequency versus FSET resistor value is shown in the Component Selection section of this datasheet. The A8654 will suspend operation if the FSET pin is shorted to GND or left open. The FSET/SYNC pin also can be used as a synchronization input that accepts an external clock to switch the A8654 from 100 kHz to 2.2 MHz and scales the slope compensation according to the synchronization frequency. When being used as a synchronization input, the applied clock pulses must satisfy the pulse width, FB Figure 1: A8654 Error Amplifier Compensation Components To stabilize the regulator, a series RC compensation network (RZ and CZ) must be connected from the error amplifier’s output (COMP pin) to GND as shown in the applications schematic. In most instances, an additional low value capacitor (CP) should be connected in parallel with the RZ-CZ compensation network to reduce the loop gain at very high frequencies. However, if the CP capacitor is too large, the phase margin of the converter may be reduced. Calculating RZ, CZ, and CP is covered in the Component Selection section of this datasheet. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 11 A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator If a fault occurs or the regulator is disabled, the COMP pin is pulled to GND via the approximately 1 kΩ internal resistor and PWM switching is inhibited. will be initiated and VOUT will ramp to its final voltage in a time set by the soft-start capacitor (CSS). To automatically enable the A8654, the EN pin may be connected directly to VIN. Slope Compensation Power MOSFETs The A8654 incorporates internal slope compensation to allow PWM duty cycles above 50% for a wide range of input/output voltages, switching frequencies, and inductor values. As shown in the functional block diagram, the slope compensation signal is added to the sum of the current sense and PWM Ramp Offset. The amount of slope compensation is scaled with the switching frequency when programming the frequency with a resistor or with an external clock. The A8654 includes an 80 mΩ, high-side N-channel MOSFET. The A8654 also includes a 55 mΩ, low-side N-channel MOSFET to provide synchronous rectification. The value of the output inductor should be chosen such that slope compensation rate SE is between 0.5× and 1× the falling slope of the inductor current (SF). Current Sense Amplifier The A8654 incorporates a high-bandwidth current sense amplifier to monitor the current through the top MOSFET. This current signal is used to regulate the peak current when the top MOSFET is turned on. The current signal is also used by the protection circuitry for the pulse-by-pulse current limit and hiccup mode short-circuit protection. Low-Dropout Operation and Undervoltage Lockout The Undervoltage Lockout behavior is described in the following Protection Features section. The A8654 is designed to allow operation when input voltage drops as low as 2.6 V which is the UVLO STOP threshold. When the input voltage falls towards the nominal output voltage, the high-side switch can remain on for maximum on-time to keep regulating the output. This is accomplished by decreasing the fSW switching frequency. In this way, the dropout from the input to output voltage is minimized. Sleep Mode with Enable input The A8654 provides a shutdown function via the EN pin. When this pin is low, the A8654 is shut down and the A8654 will enter a “sleep mode” where the internal control circuits will be shut off and draw less current from VIN. If EN goes high, the A8654 will turn on and provided there are no fault conditions, soft-start When the A8654 is disabled via the EN input being low or a fault condition, the A8654’s output stage is tri-stated by turning off both the upper and lower MOSFETs. Pulse-Width Modulation (PWM) Mode The A8654 employs fixed-frequency, peak current-mode control to provide excellent load and line regulation, fast transient response, and simple compensation. A high-speed comparator and control logic is included in the A8654. The inverting input of the PWM comparator is connected to the output of the error amplifier. The non-inverting input is connected to the sum of the current sense signal, the slope compensation signal, and a DC PWM ramp offset voltage (VPWM(OFFSET)). At the beginning of each PWM cycle, the CLK signal sets the PWM flip-flop, the bottom MOSFET is turned off, the top MOSFET is turned on, and the inductor current increases. When the voltage at the non-inverting of PWM comparator rises above the error amplifier’s output COMP, the PWM flip flop is reset and the top MOSFET is turned off, the bottom MOSFET is turned on and the inductor current decreases. The PWM flip-flop is reset dominant, so the error amplifier may override the CLK signal in certain situations. BOOT Regulator The A8654 includes a regulator to charge its boot capacitor. The voltage across the BOOT capacitor is typically 5.0 V. If the boot capacitor is missing the A8654 will detect a boot overvoltage. Similarly, if the boot capacitor is shorted the A8654 will detect a boot undervoltage. Also, the boot regulator has a current limit to protect itself during a short-circuit condition. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 12 A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator Soft-Start (Startup) and Inrush Current Control The soft-start function controls the inrush current at startup. The soft-start pin (SS) is connected to GND via a capacitor. When the A8654 is enabled and all faults are cleared, the soft-start pin will source the charging current ISS(SU) and the voltage on the soft-start capacitor CSS will ramp upward from 0 V. When the voltage at the soft-start pin exceeds the Soft-Start COMP Release Threshold (VSS(RELEASE), typically 400 mV), the error amplifier will ramp up its output voltage above the PWM Ramp Offset. At that instant, the top and bottom MOSFETs will begin switching. There is a small delay (tSS(DELAY)) between the moments of EN pin transitioning high and the soft-start voltage reaching 400 mV to initiate PWM switching. Once the A8654 begins PWM switching, the error amplifier will regulate the voltage at the FB pin to the soft-start pin voltage minus approximately 400 mV. During the active portion of softstart, the voltage at the SS pin will rise from 400 mV to 1.2 V (a difference of 800 mV), the voltage at the FB pin will rise from 0 V to 800 mV, and the regulator’s output voltage will rise from 0 V to the setpoint determined by the feedback resistor divider. During startup, the PWM switching frequency is reduced to 25% of fSW while FB is below 200 mV. If FB is above 200 mV but below 400 mV, the switching frequency is 50% of fSW. At the same time, the transconductance of the error amplifier, gm, is reduced to 1/2 of nominal value when FB is below 400 mV. When FB is above 400 mV the switching frequency will be fSW and the error amplifier’s gain will be the nominal value. The reduced switching frequencies and error amplifier’s gain are necessary to help improve output regulation and stability when VOUT is at very low voltage. When VOUT is very low, the PWM control loop requires on-time near the minimum controllable on-time and extra low duty cycles that are not possible at the nominal switching frequency. When the voltage at the soft-start pin reaches approximately 1.2 V the error amplifier will “switch over” and begin regulating the voltage at the FB to A8654’s adjusted reference voltage. The voltage at the soft-start pin will continue to rise to the internal LDO regulator’s output voltage. If the A8654 is disabled or a fault occurs, the internal fault latch is set and the capacitor at the SS pin is discharged to ground very quickly through a 2 kΩ pull-down resistor. The A8654 will clear the internal fault latch when the voltage at the SS pin decays to approximately 200 mV. However, if the A8654 enters hiccup mode, the capacitor at the SS pin is slowly discharged through a current sink, ISS(HIC). Therefore, the soft-start capacitor CSS not only controls the startup time but also the time between soft-start attempts in hiccup mode. Pre-Biased Startup If the output of the buck regulator is pre-biased at a certain output voltage level, the A8654 will modify the normal startup routine to prevent discharging the output capacitors. As described in the Soft-Start (Startup) and Inrush Current Control section, the error amplifier usually becomes active when the voltage at the soft-start pin exceeds 400 mV. If the output is pre-biased, the voltage at the FB pin will be non-zero. The A8654 will not start switching until the voltage at SS pin rises to approximately VFB + 400 mV. From then on, the error amplifier becomes active, the voltage at the COMP pin rises, PWM switching starts, and VOUT will ramp upward from the pre-bias level. Not Power-On Reset (NPOR) Output The A8654 has an inverted Power-On Reset output (NPOR) with a fixed delay of its rising edge (td(NPOR)). The NPOR output is an open-drain output so an external pull-up resistor must be used, as shown in the applications schematic. NPOR transitions high when the output voltage, sensed at the FB pin, is within regulation. The NPOR over- and undervoltage comparators incorporate a small amount of hysteresis (see EC table) and filtering (5 µs, typical) to help reduce chattering due to the voltage ripple at the FB pin. The NPOR output is immediately pulled low if either an underor overvoltage condition occurs or the A8654’s junction temperature exceeds the thermal shutdown threshold (TSD). For other faults, NPOR depends on the output voltage. Table 2 summarizes all the A8654 fault modes and their effects on NPOR. At power-up, NPOR must be initialized (set to a logic low) when VIN is relatively low. At power-down, NPOR must be held in the logic-low state as long as possible. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 13 A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator PROTECTION FEATURES The A8654 was designed to satisfy the most demanding automotive and nonautomotive applications. In this section, a description of each protection feature is described and Table 2 summarizes the protections and their operation. 5.4 5.2 5.0 4.8 Undervoltage Lockout Protection (UVLO) 4.4 ILIM (A) An Undervoltage Lockout (UVLO) comparator in the A8654 monitors the voltage at the VIN pin and keeps the regulator disabled if the voltage is below the START threshold (VUVLO(START), VIN rising) or the STOP threshold (VUVLO(STOP), VIN falling). The UVLO comparator incorporates some hysteresis VUVLO(HYS) to help reduce on/off cycling of the regulator due to the resistive or inductive drops in the VIN path during heavy loading or during startup. 4.6 4.2 4.0 MAX_550 kHz 3.8 TYP_550 kHz 3.6 MIN_550 kHz MAX_100 kHz 3.4 TYP_100 kHz MIN_100 kHz 3.2 MAX_2 MHz 3.0 TYP_2 MHz MIN_2 MHZ 2.8 Pulse-by-Pulse Overcurrent Protection (OCP) The A8654 monitors the current in the upper MOSFET, and if this current exceeds the pulse-by-pulse overcurrent threshold, then the upper MOSFET is turned off. Normal PWM operation resumes on the next clock pulse from the oscillator. The A8654 includes leading-edge blanking to prevent falsely triggering the pulse-bypulse current limit when the upper MOSFET is turned on. Because of the addition of the slope compensation ramp to the inductor current, the A8654 can deliver more current at lower duty cycles than at higher duty cycles to activate pulse-by-pulse overcurrent protection. Also, the slope compensation is not a perfectly linear function of switching frequency, so the current limit at lower switching frequency is larger compared with the limit at higher switching frequency for a given duty cycle. Figure 2 shows the typical and worst-case pulse-by-pulse current limits versus duty cycles at 2 MHz, 550 kHz, and 100 kHz. The exact current the buck regulators can support is heavily dependent on duty cycle (VIN, VOUT), ambient temperature, thermal resistance of the PCB, airflow, component selection, and nearby heat sources. Overcurrent Protection (OCP) and Hiccup Mode An OCP counter and hiccup mode circuit protect the buck regulator when the output of the regulator is shorted to ground or when the load current is too high. 0 5 10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90 95 100 Duty Cycle (%) Figure 2: Pulse-by-Pulse Current Limit vs. Duty Cycle at 100 kHz (long dashed lines), 550 kHz (solid lines) and 2 MHz (short dashed lines) When the voltage at the SS pin is below the Hiccup OCP Threshold, the hiccup mode counter is disabled. Two conditions must be met for the OCP counter to be enabled and begin counting: 1. VSS > VHIC(EN) (2.3 V) and 2. VCOMP clamped at its maximum voltage (OCL = 1) As long as these two conditions are met, the OCP counter remains enabled and will count pulses from the overcurrent comparator. If the COMP voltage decreases (OCL = 0), the OCP counter is cleared. If the OCP counter reaches OCPLIM counts (240), a hiccup latch is set and the COMP pin is quickly pulled down by a relatively low resistance (1 kΩ). The hiccup latch also enables a small current sink connected to the SS pin (ISS(HIC)). This causes the voltage at the soft-start pin to slowly ramp downward. When the voltage at the soft-start pin decays to a low-enough level (VSS(RST), 200 mVTYP) the hiccup latch is cleared and the small current sink turned off. At that instant, the SS pin will begin to source current (ISS(SU)) and the voltage at the SS pin will ramp upward. This marks the beginning of a new, normal soft-start cycle as described earlier. When the voltage at the soft-start pin exceeds the error amp voltage by approximately 400 mV, the error amp will force the voltage at the COMP pin to quickly slew upward and PWM switching will resume. If the short circuit at the regulator’s output remains, Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 14 A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator another hiccup cycle will occur. Hiccups will repeat until the short circuit is removed or the converter is disabled. If the short circuit is removed, the A8654 will soft-start normally and the output voltage will automatically recover to the desired level. Thus, hiccup mode is a very effective protection for the overload condition. It can avoid false trigger for a short-term overload. On the other hand, for the extended overload, the average power dissipation during hiccup operation is very low to keep the controller cool and enhance the reliability. Note that OCP is the only fault that results in hiccup mode being ignored while VSS < 2.3 V. BOOT Capacitor Protection The A8654 monitors the voltage across the BOOT capacitor to detect if the capacitor is missing or short-circuited. If the BOOT capacitor is missing, the regulator will enter hiccup mode after 7 PWM cycles. If the BOOT capacitor is short-circuited, the regulator will enter hiccup mode after 64 PWM cycles. For a BOOT fault, hiccup mode will operate virtually the same as described previously for an output short-circuit fault (OCP), with SS ramping up and down as a timer to initiate repeated soft-start attempts. BOOT faults are nonlatched conditions, so the A8654 will automatically recover when the fault is corrected. Overvoltage Protection (OVP) The A8654 also includes an overvoltage comparator that monitors the FB pin exceeding 110%. When the voltage at the FB pin exceeds the overvoltage threshold (VOUT(OV)), A8654 will stop PWM switching, i.e. both high- and low-side switches will be turned off, and NPOR will be pulled low. In most cases, the error amplifier will be able to maintain regulation since the synchronous output stage has excellent sink and source capability. However the error amplifier and its regulation voltage clamp are not effective when the FB pin is disconnected or when the output is shorted to the input supply. When the FB pin is disconnected from the feedback resistor divider, a tiny internal current source will force the voltage at the FB pin to rise above VOUT(OV) and disable the regulator, preventing the load from being significantly overvoltage. If a higher external voltage is accidently shorted to the A8654’s output, VFB will rise above the overvoltage threshold, triggering an OVP event and thus protecting the low-side switch. In either case, if the conditions causing the overvoltage are corrected, the regulator will automatically recover. Thermal Shutdown (TSD) The A8654 monitors its junction temperature and will stop PWM switching and pull NPOR low if it becomes too hot. Also, to prepare for a restart, the SS and COMP pins will be pulled low until VSS < VSS(RST). TSD is a nonlatched fault, so the A8654 will automatically recover if the junction temperature decreases by approximately 20°C. Pin-to-Ground and Pin-to-Pin Short Protections The A8654 was designed to satisfy the most demanding automotive and nonautomotive applications. For example, the A8654 was carefully designed “up front” to withstand a short circuit to ground at each pin without suffering damage. In addition, care was taken when defining the A8654’s pinout to optimize protection against pin-to-pin adjacent short circuits. For example, logic pins and high voltage pins were separated as much as possible. Inevitably, some low-voltage pins were located adjacent to high-voltage pins. In these instances, the low-voltage pins were designed to withstand increased voltages, with clamps and/or series input resistance, to prevent damage to the A8654. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 15 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 Table 1: Summary of A8654 Fault Modes and Operation During Fault Count, before Hiccup Dropout Foldback NPOR BOOT Charging LATCH RESET CCM according to COMP fSW/4 or fSW/2 based on VFB Depends on VOUT Not affected No Auto, remove short Forced Off Immediately Forced off Immediately Dropout Foldback Reset Depends on VOUT Not affected No Auto, remove short Pulled low only by hiccup Forced Off Immediately One Shot Diode Emulation Dropout Foldback Reset Depends on VOUT Not affected No (option avail able) Auto, remove short Die is too hot Pulled Low Immediately & latched until VSS < VSS(RST) Pulled Low Immediately & latched until VSS < VSS(RST) Forced Off Immediately Forced off Immediately Dropout Foldback Reset Pulled Low Immediately Off No Auto, Cool Down Boot Capacitor Greater than 7.0 V BOOT capacitor Open Hiccup, after 7 latched faults Pulled low by hiccup CCM according to COMP CCM according to COMP Dropout Foldback Disabled by Hiccup Depends on VOUT Off for rest of period – – Boot Capacitor On Fault BOOT Capacitor Open Hiccup, after 7 latched faults Pulled low by hiccup CCM according to COMP CCM according to COMP Dropout Foldback Disabled by Hiccup Depends on VOUT Off only during hiccup No Auto, replace capacitor Boot Capacitor Overcurrent BOOT to GND Short Not affected Not affected Not affected Pulsed at minOff Not affected Depends on VOUT Off until fault clears – – Boot Capacitor Low Voltage Normal Low VIN Operation Not affected Not affected Not affected Active during minOff period Not affected Depends on VOUT On – – Boot Capacitor Undervoltage BOOT Capacitor Short Not affected Not affected Forced Off Immediately Active during minOff period Dropout Foldback Reset Depends on VOUT On – – Low Side Switch Undervoltage Low VIN Not affected Not affected Forced Off Immediately Forced Off Immediately Dropout Foldback Reset Depends on VOUT Not affected – – VREG Undervoltage Low VIN Pulled Low Immediately & latched until VSS < VSS(RST) Pulled Low Immediately & latched until VSS < VSS(RST) Forced Off Immediately Forced Off Immediately Dropout Foldback Reset Pulled Low Immediately Off No Auto VIN Undervoltage Low VIN Pulled Low Immediately & latched until VSS < VSS(RST) Pulled Low Immediately & latched until VSS < VSS(RST) Forced Off Immediately One Shot Diode Emulation Dropout Foldback Reset Depends on VOUT Off No Auto Fault Mode Fault Cases VSS Positive Overcurrent Protection 1. Excessive IOUT 2. VOUT Shorted to GND 3. SW Soft Short To GND Negative Overcurrent Protection SW Hard Short to GND VCOMP High-Side Switch Low-Side Switch Hiccup, after 240 faults of OCL Clamped to achieve ILIM, and pulled low only by hiccup CCM according to COMP 1. Excessive Negative IOUT 2. Inductor Short Hiccup, after 1 fault of LSOC Pulled low only by hiccup SW to GND hard Short Hiccup at the end of blankOn Thermal Shutdown Continued on next page... Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 16 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 Table 1: Summary of A8654 Fault Modes and Operation (continued) During Fault Count, before Hiccup Fault Mode Hiccup Delay (after fault count is reached) Hiccup Restart or Startup (after VSS returns to VSS(RST)) FB Overvoltage Fault Cases Hiccup StartupHiccup 1. VOUT to VIN Short 2. FB Pin Open VSS VCOMP High-Side Switch Low-Side Switch Dropout Foldback NPOR BOOT Charging LATCH RESET – – – – No Auto, VFB to normal range Discharged with ISS(HIC) until VSS < VSS(RST) Pulled Low until VSS < VSS(RST) Forced Off at Start of Period One Shot Diode Emulation Dropout Foldback Reset Depends on VOUT Not affected, (off only for boot capacitor faults) (sleep option available) Charged with ISS(SU) Released from 0 V, then responds to VSS↑ CCM after VCOMP > 400 mV CCM after VCOMP > 400 mV (pulsed at minOff) Dropout Foldback Reset Depends on VOUT Not affected Not affected Forced Off Immediately One Shot Diode Emulation Dropout Foldback Reset Pulled Low Immediately Off CCM according to COMP Not affected Pulled Low Immediately Not affected No Auto, VFB to normal range Not affected FB Undervoltage Startup Not affected Not affected CCM according to COMP Feedback Less Than 400 mV Startup Not affected Not affected fSW/2 CCM according to COMP Not affected Pulled Low Not affected – – Feedback Less Than 200 mV StartupVOUT to GND Short Not affected Not affected fSW/4 CCM according to COMP fSW already at 1/4 Pulled Low Not affected – – Pulled Low Immediately & latched until VSS < VSS(RST) Pulled Low Immediately & latched until VSS < VSS(RST) Forced Off Immediately One Shot Diode Emulation Not affected Depends on VOUT Off – – FSET Resistor Fault 1.FSET to GND short 2.FSET pulled high 3.Low R 4.High R SS shorted to VIN SS to VIN short Clamped to zener voltage internally Not affected CCM according to COMP CCM according to COMP Not affected Depends on VOUT Not affected – – SS shorted to GND SS to GND short At GND Loop response only CCM according to COMP CCM according to COMP Not affected Depends on VOUT Not affected – – COMP shorted to GND COMP to GND short Not affected At GND CCM according to COMP CCM according to COMP Not affected Depends on VOUT Not affected – – Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 17 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 DESIGN AND COMPONENT SELECTION Setting the Output Voltage 2.0 × 103 1.6 × 10 3 1.4 × 10 3 1.2 × 103 1 × 10 3 800 600 400 CFB FB Pin 1.8 × 103 Frequency (kHz) The output voltage of the regulator is determined by connecting a resistor divider from the output node (VOUT) to the FB pin as shown in Figure 3. There are trade-offs when choosing the value of the feedback resistors. If the series combination (RFB1 + RFB2) is too low, then the light load efficiency of the regulator will be reduced. So, to maximize the efficiency, it is best to choose higher values of resistors. On the other hand, if the parallel combination (RFB1//RFB2) is too high, then the regulator may be susceptible to noise coupling onto the FB pin. 1% resistors are recommended to maintain the output voltage accuracy. 200 VOUT 0 10 RFB1 20 30 40 50 60 70 80 90 100 110 120 130 140 150 160 RFSET (kΩ) RFB2 Figure 4: PWM Switching Frequency versus RFSET Figure 3: Connecting a Feedback Divider to Set the Output Voltage The feedback resistors must satisfy the ratio shown in equation 1 below to produce a desired output voltage (VOUT). VOUT RFB1 –1 RFB2 = 0.8 V (1) A phase lead capacitor (CFB) can be connected in parallel with RFB1 to increase the phase and gain margins. It adds an additional zero and pole to the compensation network and boosts the loop phase at the crossover frequency. In general, CFB should be less than 25 pF. If CFB is too large, it will have no effect. If CFB is used, CFB can be calculated from equation 2: CFB = 1 2πRFB1fc (2) where fc is crossover frequency. PWM Switching Frequency (fSW, RFSET) The PWM switching frequency is set by connecting a resistor from the FSET pin to ground. Figure 4 is a graph showing the relationship between the typical switching frequency (y-axis) and the FSET resistor RFSET (x-axis). For a desired switching frequency (fSW), the FSET resistor can be calculated using equation 3, where fSW is in kHz and RFSET is in kΩ. RFSET = 26000 – 2.2 fSW (3) When the PWM switching frequency is chosen, the designer should be aware of the minimum controllable on-time, tON(MIN) of the A8654. If the system’s required on-time is less than the minimum controllable on-time, pulse skipping will occur and the output voltage will have increased ripple or oscillations. The PWM switching frequency should be calculated using equation 4, where VOUT is the output voltage, tON(MIN) is the minimum controllable on-time of the A8654 (See EC table), and VIN(MAX) is the maximum required operational input voltage (not the peak surge voltage). fSW < VOUT tON(MIN) × VIN(MAX) (4) If the A8654 synchronization function is employed, the base switching frequency should be chosen such that pulse skipping will not occur at the maximum synchronized switching frequency according to equation 4 (i.e. 1.5 × fSW is less than the result from equation 4). Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 18 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 Output Inductor (LO) Output Capacitors For a peak current-mode regulator, it is common knowledge that without adequate slope compensation, the system will become unstable when the duty cycle is near or above 50%. However, the slope compensation in the A8654 is a fixed value (SE). Therefore, it is important to calculate an inductor value so the falling slope of the inductor current (SF) will work well with the A8654’s slope compensation. Equations 5 and 6 can be used to calculate a range of values for the output inductor based on the well-known approach of providing slope compensation that matches 50% to 100% of the down slope of the inductor current. In equation 5, use the slope compensation (SE ), which is a function of switching frequency according to equation 6. The output capacitors filter the output voltage to provide an acceptable level of ripple voltage, and they store energy to help maintain voltage regulation during a load transient. The voltage rating of the output capacitors must support the output voltage with sufficient design margin. The output voltage ripple (ΔVOUT) is a function of the output capacitors parameters: CO, ESRCO, ESLCO. VOUT VOUT ≤ L O ≤ 2 × SE SE 2 SE = 0.0445 × fSW + 0.5612 × fSW (5) (6) VOUT = IL × ESRCO + IL VIN – VOUT × ESLCO + LO 8fSWCO The type of output capacitors will determine which terms of equation 9 are dominant. For ceramic output capacitors, the ESRCO and ESLCO are virtually zero so the output voltage ripple will be dominated by the third term of equation 9. VOUT = SE is in A/µs, fSW is in MHz, and LO will be in µH (9) IL 8fSWCO (10) If equations 5 or 6 yield an inductor value that is not a standard value, then the next highest available value should be used. The final inductor value should allow for 10%-20% of initial tolerance and 20%-30% of inductor saturation. To reduce the voltage ripple of a design using ceramic output capacitors, simply increase the total capacitance, reduce the inductor current ripple (i.e. increase the inductor value), or increase the switching frequency. The saturation current of the inductor should be higher than the peak current capability of the A8654. Ideally, for output shortcircuit conditions, the inductor should not saturate at the highest pulse-by-pulse current limit at minimum duty cycle; this may be too costly. At the very least, the inductor should not saturate at the peak operating current according to equation 7. In equation 7 VIN(MAX) is the maximum continuous input voltage. For electrolytic output capacitors, the value of capacitance will be relatively high, so the third term in equation 9 will be very small and the output voltage ripple will be determined primarily by the first two terms of equation 9. IPEAK = 5.3 – SE × VOUT 1.15 × fSW × VIN(MAX) (7) Subtracting half of the inductor ripple current from equation 7 gives an interesting equation to predict the typical DC load capability of the regulator at a given duty cycle (D), S ×D V × (1 – D) IOUT(DC) ≤ 5.3 – E – OUT fSW 2 × fSW × LO (8) After an inductor is chosen, it should be tested during output short-circuit conditions. The inductor current should be monitored using a current probe. A good design should ensure neither the inductor nor the regulator are damaged when the output is shorted to ground at maximum input voltage and the highest expected ambient temperature. VOUT = IL × ESRCO + VIN – VOUT × ESLCO LO (11) To reduce the voltage ripple of a design using electrolytic output capacitors, simply decrease the equivalent ESRCO and ESLCO by using a high(er) quality capacitor, or add more capacitors in parallel, or reduce the inductor current ripple (i.e. increase the inductor value). The ESR of some electrolytic capacitors can be quite high, so Allegro recommends choosing a quality capacitor for which the ESR or the total impedance is clearly documented in the datasheet. Also, the ESR of electrolytic capacitors usually increases significantly at cold ambients, as much as 10×, which increases the output voltage ripple and in most cases reduces the stability of the system. The transient response of the regulator depends on the quantity and type of output capacitors. In general, minimizing the ESR of Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 19 the output capacitance will result in a better transient response. The ESR can be minimized by simply adding more capacitors in parallel or by using higher quality capacitors. At the instant of a fast load transient (di/dt), the output voltage will change by the amount di (12) ESLCO VOUT = ILOAD × ESRCO + dt After the load transient occurs, the output voltage will deviate from its nominal value for a short time. This time will depend on the system bandwidth, the output inductor value, and output capacitance. Eventually, the error amplifier will bring the output voltage back to its nominal value. The speed at which the error amplifier will bring the output voltage back to its setpoint mainly depends on the closed-loop bandwidth of the system. A higher bandwidth usually results in a shorter time to return to the nominal voltage. However, with a higher bandwidth system it may be more difficult to obtain acceptable gain and phase margins. Selection of the compensation components (RZ, CZ, CP) are discussed in more detail in the Compensation Components section of this datasheet. Input Capacitors Three factors should be considered when choosing the input capacitors. First, they must be chosen to support the maximum expected input surge voltage with adequate design margin. Second, the capacitor RMS current rating must be higher than the expected RMS input current to the regulator. Third, they must have enough capacitance and a low enough ESR to limit the input voltage dV/dt to something much less than the hysteresis of the VIN pin UVLO circuitry (VUVLO(HYS), nominally 800 mV for the A8654) at maximum loading and minimum input voltage. The input capacitors must deliver the RMS current according to: IRMS = IO D × (1 – D) (13) where the duty cycle D is D ≈ VOUT / VIN. Figure 5 shows the normalized input capacitor RMS current versus duty cycle. To use this graph, simply find the operational duty cycle (D) on the x-axis and determine the input/output current multiplier on the y-axis. For example, at a 20% duty cycle, the input/output current multiplier is 0.40. Therefore, if the regulator is delivering 3.0 A of steady-state load current, the input capacitor(s) must support 0.40 × 3.0 A or 1.2 ARMS. IRMS / IOUT Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 0.55 0.50 0.45 0.40 0.35 0.30 0.25 0.20 0.15 0.10 0.05 0.00 0 10 20 30 60 40 50 Duty Cycle (%) 70 80 90 100 Figure 5: Input Capacitor Ripple vs. Duty Cycle The input capacitor(s) must limit the voltage deviations at the VIN pin to something significantly less than the A8654’s UVLO hysteresis during maximum load and minimum input voltage. The minimum input capacitance can be calculated as follows: CIN ≥ IOUT × D × (1 – D) 0.85 × fSW × ΔVIN(MIN) (14) Where ΔVIN(MIN) is chosen to be much less than the hysteresis of the VIN UVLO comparator (ΔVIN(MIN) ≤ 150 mV is recommended), and fSW is the nominal PWM frequency. The D × (1 – D) term in equation 13 has an absolute maximum value of 0.25 at 50% duty cycle. So, for example, a very conservative design based on IOUT = 3.0 A, fSW = 85% of 425 kHz, D × (1 – D) = 0.25, and ΔVIN = 150 mV, CIN ≥ 3.0 A × 0.25 = 14 µF 361 kHz × 150 mV A good design should consider the DC bias effect on a ceramic capacitor: as the applied voltage approaches the rated value, the capacitance value decreases. This effect is very pronounced with the Y5V and Z5U temperature characteristic devices (as much as 90% reduction) so these types should be avoided. The X5R and X7R type capacitors should be the primary choices due to their stability versus both DC bias and temperature. For all ceramic capacitors, the DC bias effect is even more pronounced on smaller case sizes, so a good design will use the largest affordable case size (i.e. 1206 or 1210). Also, it is advisable to select input capacitors with plenty of design margin in the voltage rating to accommodate the worst-case transient input voltage (such as a load dump as high as 40 V for automotive applications). Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 20 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 Bootstrap Capacitor A bootstrap capacitor must be connected between the BOOT and SW pins to provide the floating gate drive to the high-side MOSFET. Usually, 100 nF is an adequate value. This capacitor should be a high-quality ceramic capacitor, such as an X5R or X7R, with a voltage rating of at least 16 V. Soft-Start and Hiccup Mode Timing (CSS) The soft-start time of the A8654 is determined by the value of the capacitance at the soft-start pin (CSS). When the A8654 is enabled, the voltage at the soft-start pin will start from 0 V and will be charged by the soft-start current (ISS(SU)). However, PWM switching will not begin instantly because the voltage at the soft-start pin must rise above 400 mV. The soft-start delay (tSS(DELAY)) can be calculated using equation below, tSS(DELAY) = C SS × ( 400 mV ISS(SU) ) (15) If the A8654 is starting with a very heavy load, a very fast softstart time may cause the regulator to exceed the pulse-by-pulse overcurrent threshold. This occurs because the sum of the full load current, the inductor ripple current, and the additional current required to charge the output capacitors ICO = CO × VOUT / tSS is higher than the pulse-by-pulse current threshold, as shown in Figure 6. This phenomena is more pronounced when using high value electrolytic type output capacitors. } ILIM ILOAD Output Capacitor Current (ICO) tSS Figure 6: Output Current (ICO) During Startup To avoid prematurely triggering hiccup mode, the soft-start capacitor (CSS) should be calculated according to equation below, CSS ≥ ISS(SU) × VOUT × CO 0.8 V × ICO (16) where VOUT is the output voltage, CO is the output capacitance, ICO is the amount of current allowed to charge the output capacitance during soft-start (recommend 0.1 A < ICO < 0.3 A). Higher values of ICO result in faster soft-start times. Howewer, lower values of ICO ensure that hiccup mode is not falsely triggered. Allegro recommends starting the design with an ICO of 0.1 A and increasing it only if the soft-start time is too slow. If a non-standard capacitor value for CSS is calculated, the next larger value should be used. The output voltage ramp time (tSS) can be calculated by using either of the following methods: COUT CSS tSS = VOUT × I or 0.8 V × I CO SS(SU) (17) When the A8654 is in hiccup mode, the soft-start capacitor is used as a timing capacitor and sets the hiccup period. The softstart pin charges the soft-start capacitor with ISS(SU) during a startup attempt and discharges the same capacitor with ISS(HIC) between startup attempts. Because the ratio of ISS(SU)/ISS(HIC) is approximately 4:1, the time between hiccups will be about four times as long as the startup time. Therefore, the effective duty cycle will be very low and the junction temperature will be kept low. Compensation Components (RZ, CZ, CP) To compensate the system, it is important to understand where the buck power stage, load resistance, and output capacitance form their poles and zeros in frequency. Also, it is important to understand that the (Type II) compensated error amplifier introduces a zero and two more poles and where these should be placed to maximize the system’s stability, provide a high bandwidth, and optimize the transient response. First, consider the power stage of the A8654, the output capacitors, and the load resistance. This circuitry is commonly referred as the “control to output” transfer function. The low frequency gain of this section depends on the COMP to SW current gain (gmPOWER), and the value of the load resistor (RL). The DC gain (GCO(0HZ)) of the control-to-output is: Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 21 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 GCO(0Hz) = gmPOWER × RL (18) The control to output transfer function has a pole (fP1) formed by the output capacitance (COUT) and load resistance (RL) at: fP1 = 1 2π × RL × COUT (19) The control to output transfer function also has a zero (fZ1) formed by the output capacitance (COUT) and its associated ESR fZ1 = 1 2π × ESR × COUT (20) For a design with very low-ESR type output capacitors (i.e. ceramic or OSCON output capacitors), the ESR zero, fZ1, is usually at a very high frequency, so it can be ignored. On the other hand, if the ESR zero falls below or near the 0 dB crossover frequency of the system (as is the case with electrolytic output capacitors), then it should be cancelled by the pole formed by the CP capacitor and the RZ resistor (discussed and identified later as fP3). Next, consider the feedback resistor divider, (RFB1 and RFB2), the error amplifier (gm), and its compensation network RZCZ-CP. It greatly simplifies the transfer function derivation if RO ≫ RZ, and CZ ≫ CP (where RO is the error amplifier output impedance). In most cases, RO > 2 MΩ, 1 kΩ < RZ < 100 kΩ, 220 pF < CZ < 47 nF, and CP < 50 pF, so the following equations are very accurate. The low frequency gain of the control section (GC(0Hz)) is formed by the feedback resistor divider and the error amplifier. It can be calculated using equation 21: RFB2 × gm× R O RFB1 + RFB2 VFB = × gm× R O VOUT VFB = × A VOL VOUT GC(0Hz ) = (21) where VOUT is the output voltage, VFB is the reference voltage (0.8 V), gm is the error amplifier transconductance (750 µA/V), and RO is the error amplifier output impedance (AVOL/gm). The transfer function of the Type-II compensated error amp has a (very) low frequency pole (fP2) dominated by the output error amplifier’s output impedance RO and the CZ compensation capacitor, fP2 = 1 2π × RO × CZ (22) The transfer function of the Type-II error amp also has a low frequency zero (fZ2) dominated by the RZ resistor and the CZ capacitor. fZ2 = 1 2π × RZ × CZ (23) Lastly, the transfer function of the Type-II compensated error amp has a (very) high frequency pole (fP3) dominated by the RZ resistor and the CP capacitor fP3 = 1 2π × RZ × CP (24) Placing fZ2 just above fP1 will result in excellent phase margin, but relatively slow transient recovery time. The magnitude and phase of the entire system are simply the sum of the error amp response and the control-to-output response. A Generalized Tuning Procedure 1. Choose the system bandwidth, fC, the frequency at which the magnitude of the gain will cross 0 dB. Recommended values for fC based on the PWM switching frequency are fSW/20 < fC < fSW/7.5. A higher value of fC will generally provide a better transient response while a lower value of fC will be easier to obtain higher gain and phase margins. 2. Calculate the RZ resistor value to set the desired system bandwidth (fC), VOUT 2 × π × COUT RZ = fC × × (25) VFB gmPOWER × gm 3. Determine the frequency of the pole (fP1) formed by COUT and RL by using equation 19 (repeated here). 1 fP1 = 2π × RL × COUT 4. Calculate a range of values for the CZ capacitor, 4 1 < CZ < 2 × π × RZ × fC 2 × π × RZ × 1.5 × fP1 Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com (26) 22 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 To maximize system stability (i.e. have the most gain margin), use a higher value of CZ. To optimize transient recovery time at the expense of some phase margin, use a lower value of CZ. 5. Calculate the frequency of the ESR zero (fZ1) formed by the output capacitor(s) by using equation 20 (repeated here). 1 fZ1 = 2π × ESR × COUT A. If fZ1 is at least 1 decade higher than the target crossover frequency (fC), then fZ1 can be ignored. This is usually the case for a design using ceramic output capacitors. Use equation 24 to calculate the value of CP by setting fP3 to either 5 × fC or fSW/2, whichever is higher. B. On the other hand, if fZ1 is near or below the target crossover frequency (fC) then use equation 24 to calculate the value of CP by setting fP3 equal to fZ1. This is usually the case for a design using high ESR electrolytic output capacitors. Referring to Typical Application Diagram on the front page, several typical designs are provided in Table 2 for A8654. Table 2: Recommended Components Values for Three Typical Designs fSW VOUT RFSET LO CO RZ + CZ // CP RFB1 RFB2 500 kHz 5.0 V 52.3 kΩ 10 µH (74437368100) 44 µF 14 kΩ + 2.7 nF/33 pF 24.9 kΩ 4.75 kΩ 1 MHz 3.3 V 23.7 kΩ 6.8 µH (74437368068) 44 µF 14 kΩ + 2.2 nF/15 pF 16.5 kΩ 5.23 kΩ 2 MHz 5.0 V 10.5 kΩ 6.8 µH (74437368068) 32 µF 37.4 kΩ + 1.8 nF/4.7 pF 24.9 kΩ 4.75 kΩ Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 23 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 POWER DISSIPATION AND THERMAL CALCULATIONS The power dissipated in the A8654 is the sum of the power dissipated from the VIN supply current (PIN), the power dissipated due to the switching of the high-side power MOSFET (PSW1), the power dissipated due to the RMS current being conducted by the high-side MOSFET (PCOND1) and low-side MOSFET (PCOND2), and the power dissipated by both gate drivers (PDRIVER). The power dissipated from the VIN supply current can be calculated using equation 27, PIN = VIN × IQ + (VIN – VGS ) × (QG1 + QG2 ) × fSW (27) Similarly, the conduction losses dissipated by the low-side MOSFET while it is conducting can be calculated by the following equation: PCOND2 = I ( 1– RMS(FET) × R DS(ON)LS = 2 )( ) VOUT ΔI 2 × I OUT + L × R DS(ON)LS VIN 12 (30) 2 where IOUT is the regulator output current, ΔIL is the peak-to-peak inductor ripple current, where RDS(ON)HS is the on-resistance of the high-side MOSFET, VIN is the input voltage, IQ is the input quiesent current drawn by the A8654 (see EC table), VGS is the MOSFET gate drive voltage (typically 5 V), QG1 and QG2 is the internal high-side and low-side MOSFET gate charges (approximately 5.8 nC and 10.4 nC, respectively), and fSW is the PWM switching frequency. The power dissipated by the high-side MOSFET during PWM switching can be calculated using equation 28, VIN × IOUT × (tr + tf ) × fSW PSW1 = 2 (28) where RDS(ON)LS is the on-resistance of the low-side MOSFET The RDS(ON) of both MOSFETs have some initial tolerance plus an increase from self-heating and elevated ambient temperatures. A conservative design should accomodate an RDS(ON) with at least a 15% initial tolerance plus 0.39%/°C increase due to temperature. The power dissipated from the low-side MOSFET body diode during the non-overlap time can be calculated as follows: PNO = VSD × IOUT × 2 × tNO × fSW (31) where VSD is the source-to-drain voltage of the low-side MOSFET (typically 0.60 V), and tNO is the non-overlap time (15 ns(typ)) VIN is the input voltage, IOUT is the regulator output current, The sum of the power dissipated by the internal gate driver can be calculated using equation 32, fSW is the PWM switching frequency, and tr and tf are the rise and fall times measured at the SW node. where The exact rise and fall times at the SW node will depend on the external components and PCB layout, so each design should be measured at full load. Approximate values for both tr and tf range from 10 to 20 ns. The power dissipated by the high-side MOSFET while it is conducting can be calculated using equation 29, PCOND1 = I 2 RMS,FET × R DS(ON)HS = VOUT I 2 × I OUT + L × R DS(ON)HS VIN 12 (29) ( )( 2 ) PDRIVER = (QG1 + QG2) × VGS × fSW (32) VGS is the gate drive voltage (typically 5 V), QG1 and QG2 is the gate charges to drive high-side and low-side MOSFETs to VGS = 5 V (about 5.8 nC and 10.4 nC respectively), and fSW is the PWM switching frequency. Finally, the total power dissipated by the A8654 (PTOTAL) is the sum of the previous equations, PTOTAL = PIN + PSW1 + PCOND1 + PCOND2 + PNO + PDRIVER (33) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 24 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 The average junction temperature can be calculated with the equation below, TJ = PTOTAL × RθJA + TA (34) where PTOTAL is the total power dissipated from equation 33, RθJA is the junction-to-ambient thermal resistance (34°C/W on a 4-layer PCB), and TA is the ambient temperature. The maximum junction temperature will be dependent on how efficiently heat can be transferred from the PCB to the ambient air. It is critical that the thermal pad on the bottom of the IC should be connected to at least one ground plane using multiple vias. As with any regulator, there are limits to the amount of heat that can be dissipated before risking thermal shutdown. There are trade-offs between ambient operating temperature, input voltage, output voltage, output current, switching frequency, PCB thermal resistance, airflow, and other nearby heat sources. Even a small amount of airflow will reduce the junction temperature considerably. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 25 A8654 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator PCB COMPONENT PLACEMENT AND ROUTING A good PCB layout is critical for the A8654 to provide clean, stable output voltages. Follow these guidelines to ensure a good PCB layout. Figure 7 shows a typical buck converter schematic with the critical power paths/loops. Figure 8 shows an example PCB component placement and routing with the same critical power paths/loops from the schematic. 1. Place the ceramic input capacitors as close as possible to the VIN pin and GND pins to make the loop area minimal; and the traces of the input capacitors to VIN pin should be short and wide to minimize the inductance. This critical loop is shown as Trace 1 in Figure 7 and Figure 8. The larger input capacitor can be located further away from VIN pin. The input capacitors and A8654 IC should be on the same side of the board with traces on the same layer. 2. The loop from the input supply and capacitors, through the high-side MOSFET, into the load via the output inductor, and back to ground should be minimized with relatively wide traces. 3. When the high-side MOSFET is off, free-wheeling current flows from ground, through the synchronous low-side MOSFET, into the load via the output inductor, and back to ground. This loop should be minimized and have relatively wide traces. This loop is shown as Trace 2 in Figure 7 and Figure 8. 4. Place the output capacitors relatively close to the output inductor (LO) and the A8654. Ideally, the output capacitors, output inductor and the controller IC A8654 should be on the same layer. Connect the output inductor and the output capacitors with a fairly wide trace. The output capacitors must use a ground plane to make a very low-inductance connection to the GND. These critical connections are shown as Trace 3 in Figure 7. 5. Place the output inductor (Lo) as close as possible to the SW pin with short and wide traces. This critical trace is shown as Trace 4 in Figure 7 and Figure 8. The SW node voltage transitions from 0 V to VIN and with a high dV/dt rate. This node is the root cause of many noise issues. It is suggested to 6. 7. 8. 9. 10. 11. 12. 13. 14. minimize the SW copper area to minimize the coupling capacitance between SW node and other noise-sensitive nodes. However the SW node area cannot be too small in order to conduct high current. A ground copper area can be placed beneath the SW node to provide additional shielding. Also, keep low-level analog signals (like FB, COMP) away from the SW polygon. Place the feedback resistor divider (RFB1 and RFB2) very close to the FB pin. Make the ground side of RFB2 as close as possible to the A8654. Place the compensation components (RZ, CZ, and CP) as close as possible to the COMP pin. Also make the ground side of CZ and CP as close as possible to the A8654. Place the FSET resistor as close as possible to the SYNC/ FSET pin. Place the soft-start capacitor CSS as close as possible to the SS pin. The output voltage sense trace (from VOUT to RFB1) should be connected as close as possible to the load to obtain the best load regulation. Place the bootstrap capacitor (CBOOT) near the BOOT pin and keep the routing from this capacitor to thw SW polygon as short as possible. When connecting the input and output ceramic capacitors, use multiple vias to GND and place the vias as close as possible to the pads of the components. Do not use thermal reliefs around the pads for the input and output ceramic capacitors. To minimize PCB losses and improve system efficiency, the input and output traces should be as wide as possible and be duplicated on multiple layers, if possible. The thermal pad under the A8654 IC should be connected to the GND plane (preferably on the top and bottom layer) with as many vias as possible. Allegro recommends vias with an approximately 0.25 to 0.30 mm hole and a 0.13 and 0.18 mm ring. EMI/EMC issues are always a concern. Allegro recommends having locations for an RC snubber from SW to ground. The resistor should be 0805 or 1206 size. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 26 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 1 VIN RFB1 CIN FB LO SW SS VOUT 4 VREG SYNC/FSET CO COMP CSS RFB2 CP RFSET CZ Load 2 RZ SGND PGND 1 3 Figure 7: Typical Synchronous Buck Regulator A single-point ground is recommended, which could be the exposed thermal pad under the IC. 2 1 4 Figure 8: Example PCB Component Placement and Routing Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 27 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 PACKAGE OUTLINE DRAWING For Reference Only – Not for Tooling Use (Reference MO-153 ABT) Dimensions in millimeters. NOT TO SCALE Dimensions exclusive of mold flash, gate burrs, and dambar protrusions Exact case and lead configuration at supplier discretion within limits shown 0.65 0.45 8º 0º 5.00 ±0.10 16 16 0.20 0.09 1.70 B 3 NOM 4.40 ±0.10 6.40 ±0.20 A 1 3.00 6.10 0.60 ±0.15 1.00 REF 2 3 NOM 1 2 0.25 BSC Branded Face C 16X 0.10 C 0.30 0.19 3.00 SEATING PLANE GAUGE PLANE C PCB Layout Reference View SEATING PLANE 1.20 MAX 0.65 BSC NNNNNNN 0.15 0.00 YYWW LLLL A Terminal #1 mark area B Exposed thermal pad (bottom surface); dimensions may vary with device C Reference land pattern layout (reference IPC7351 SOP65P640X110-17M); All pads a minimum of 0.20 mm from all adjacent pads; adjust as necessary to meet application process requirements and PCB layout tolerances; when mounting on a multilayer PCB, thermal vias at the exposed thermal pad land can improve thermal dissipation (reference EIA/JEDEC Standard JESD51-5) D Branding scale and appearance at supplier discretion 1 D Standard Branding Reference View N = Device part number = Supplier emblem Y = Last two digits of year of manufacture W= Week of manufacture L = Characters 5-8 of lot number Figure 9: Package LP, 16-Pin eTSSOP with Exposed Thermal Pad Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 28 Wide Input Voltage, Adjustable Frequency, 3 A, 2 MHz Synchronous Buck Regulator A8654 Revision Table Number Date – February 10, 2015 1 March 4, 2016 2 April 6, 2016 Description Initial Release Added AEC-Q100 qualification to Features and Benefits Updated Electrical Characteristics table: SW Leakage Current, PWM Switching Frequency (page 6), Peak Inductor (Pulse-by-Pulse) Current Limit, Slope Compensation, SS Maximum Charge Voltage, SS Switching Frequency, VOUT UV Threshold (page 7); Multiple editorial changes (all pages). Copyright ©2016, Allegro MicroSystems, LLC Allegro MicroSystems, LLC reserves the right to make, from time to time, such departures from the detail specifications as may be required to permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current. Allegro’s products are not to be used in any devices or systems, including but not limited to life support devices or systems, in which a failure of Allegro’s product can reasonably be expected to cause bodily harm. The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, LLC assumes no responsibility for its use; nor for any infringement of patents or other rights of third parties which may result from its use. For the latest version of this document, visit our website: www.allegromicro.com Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 29