LMR33630CQRNXRQ1

LMR33630-Q1 SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 LMR33630-Q1 3.8-V to 36-V, 3-A Synchronous Step-Down Voltage Converter 1 Features 3 Description • The LMR33630-Q1 automotive-qualified regulator is an easy-to-use, synchronous, step-down DC/DC converter that delivers best-in-class efficiency for rugged applications. The LMR33630-Q1 drives up to 3 A of load current from an input of up to 36 V. The LMR33630-Q1 provides high light load efficiency and output accuracy in a very small solution size. Features such as a power-good flag and precision enable provide both flexible and easy-touse solutions for a wide range of applications. The LMR33630-Q1 automatically folds back frequency at light load to improve efficiency. Integration eliminates most external components and provides a pinout designed for simple PCB layout. Protection features include thermal shutdown, input undervoltage lockout, cycle-by-cycle current limit, and hiccup short-circuit protection. The LMR33630-Q1 is available in a 12-pin 3 mm × 2 mm next generation VQFN package with wettable flanks. • • • • • AEC-Q100 qualified for automotive applications: – Temperature grade 1: –40°C to +125°C, TA Functional Safety-Capable – Documentation available to aid functional safety system design Configured for rugged automotive applications – Input voltage range: 3.8 V to 36 V – Output voltage range: 1 V to 24 V – Output current: 3 A – 75-mΩ/50-mΩ RDS-ON power MOSFETs – Peak-current-mode control – Short minimum on-time of 68 ns – Frequency: 400 kHz, 1.4 MHz, 2.1 MHz – Integrated compensation network Low EMI and switching noise – HotRod™ package – Parallel input current paths High power conversion at all loads – Peak efficiency > 95% – Low shutdown quiescent current of 5 µA – Low operating quiescent current of 25 µA Create a custom design using the LMR33630-Q1 with the WEBENCH® Power Designer 2 Applications • • Device Information PART NUMBER LMR33630-Q1 (1) PACKAGE(1) VQFN (12) BODY SIZE (NOM) 3.00 mm × 2.00 mm For all available packages, see the orderable addendum at the end of the data sheet. Infotainment and cluster : USB charge Telematics control unit BOOT VIN VIN CBOOT CIN EN SW L1 VOUT COUT PGND VCC PG RFBT CVCC FB RFBB AGND Simplified Schematic Minimum Component Example An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications, intellectual property matters and other important disclaimers. PRODUCTION DATA. LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 Table of Contents 1 Features............................................................................1 2 Applications..................................................................... 1 3 Description.......................................................................1 4 Revision History.............................................................. 2 5 Pin Configuration and Functions...................................4 6 Specifications.................................................................. 5 6.1 Absolute Maximum Ratings........................................ 5 6.2 ESD Ratings............................................................... 5 6.3 Recommended Operating Conditions.........................5 6.4 Thermal Information....................................................6 6.5 Electrical Characteristics.............................................6 6.6 Timing Characteristics.................................................8 6.7 System Characteristics............................................... 9 6.8 Typical Characteristics.............................................. 10 7 Detailed Description...................................................... 11 7.1 Overview................................................................... 11 7.2 Functional Block Diagram......................................... 11 7.3 Feature Description...................................................12 7.4 Device Functional Modes..........................................15 8 Application and Implementation.................................. 19 8.1 Application Information............................................. 19 8.2 Typical Application.................................................... 19 8.3 What to Do and What Not to Do............................... 30 9 Power Supply Recommendations................................31 10 Layout...........................................................................32 10.1 Layout Guidelines................................................... 32 10.2 Layout Example...................................................... 34 11 Device and Documentation Support..........................35 11.1 Device Support........................................................35 11.2 Documentation Support.......................................... 35 11.3 Support Resources................................................. 35 11.4 Receiving Notification of Documentation Updates.. 35 11.5 Trademarks............................................................. 35 11.6 Electrostatic Discharge Caution.............................. 36 11.7 Glossary.................................................................. 36 4 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Revision B (March 2019) to Revision C (October 2020) Page • Added functional safety bullet in the Features ...................................................................................................1 • Added low EMI and switching noise bullet to the Features ............................................................................... 1 • Updated the numbering format for tables, figures and cross-references throughout the document. .................1 Changes from Revision A (November 2018) to Revision B (March 2019) Page • Changed block diagram to fix drawing error..................................................................................................... 11 Changes from Revision * (June 2018) to Revision A (November 2018) Page • First release of production-data data sheet ....................................................................................................... 1 2 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 Device Comparison Table DEVICE OPTION PACKAGE LMR33630AQRNX LMR33630BQRNX RNX (12-pin VQFN) 3 × 2 × 0.85 mm LMR33630CQRNX FREQUENCY RATED CURRENT 400 kHz 3A 1400 kHz 3A 2100 kHz 3A OUTPUT VOLTAGE Adjustable Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 3 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 5 Pin Configuration and Functions SW 12 11 PGND PGND 1 VIN 2 10 VIN NC 3 9 EN BOOT 4 8 PG 5 VCC 6 7 AGND FB Figure 5-1. 12-Pin VQFN RNX Package (Top View) Table 5-1. Pin Functions PIN TYPE DESCRIPTION NO. NAME 1, 11 PGND G Power ground terminal. Connect to system ground and AGND. Connect to a bypass capacitor with short wide traces. 2, 10 VIN P Input supply to regulator. Connect a high-quality bypass capacitor(s) directly to this pin and PGND. 3 NC — On the VQFN package, connect the SW pin to NC on the PCB. This simplifies the connection from the CBOOT capacitor to the SW pin. This pin has no internal connection to the regulator. 4 BOOT P Boot-strap supply voltage for internal high-side driver. Connect a high-quality 100-nF capacitor from this pin to the SW pin. On the VQFN package connect the SW pin to NC on the PCB. This simplifies the connection from the CBOOT capacitor to the SW pin. 5 VCC P Internal 5-V LDO output. Used as supply to internal control circuits. Do not connect to external loads. Can be used as logic supply for power-good flag. Connect a high quality 1-µF capacitor from this pin to GND. 6 AGND G Analog ground for regulator and system. Ground reference for internal references and logic. All electrical parameters are measured with respect to this pin. Connect to system ground on PCB. 7 FB A Feedback input to regulator. Connect to tap point of feedback voltage divider. DO NOT FLOAT. DO NOT GROUND. 8 PG A Open drain power-good flag output. Connect to suitable voltage supply through a current limiting resistor. High = power OK, low = power bad. Flag pulls low when EN = Low. Can be left open when not used. 9 EN A Enable input to regulator. High = ON, low = OFF. Can be connected directly to VIN; DO NOT FLOAT. 12 SW P Regulator switch node. Connect to power inductor. On the VQFN package the SW pin must be connected to NC on the PCB. This simplifies the connection from the CBOOT capacitor to the SW pin. A = Analog, P = Power, G = Ground 4 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 6 Specifications 6.1 Absolute Maximum Ratings Over the recommended operating junction temperature range(1) PARAMETER MIN MAX UNIT VIN to PGND –0.3 38 EN to AGND(2) –0.3 VIN + 0.3 FB to AGND –0.3 5.5 0 22 AGND to PGND –0.3 0.3 SW to PGND –0.3 VIN + 0.3 SW to PGND less than 100-ns transients –3.5 38 BOOT to SW –0.3 5.5 VCC to AGND(4) –0.3 5.5 TJ Junction temperature(3) –40 150 °C Tstg Storage temperature –55 150 °C PG to AGND(2) Voltages (1) (2) (3) (4) V V Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. The voltage on this pin must not exceed the voltage on the VIN pin by more than 0.3 V Operating at junction temperatures greater than 125°C, although possible, degrades the lifetime of the device. Under some operating conditions the VCC LDO voltage may increase beyond 5.5V. 6.2 ESD Ratings VALUE V(ESD) (1) Electrostatic discharge Human-body model (HBM), per AEC Q100-002 (1) HBM ESD Classification Level 2 ±2500 Charged-device model (CDM), per AEC Q100-011 CDM ESD Classification Level C5 ±750 UNIT V AEC Q100-002 indicates that HBM stressing shall be in accordance with ANSI/ESDA/JEDEC JS-001 specification. 6.3 Recommended Operating Conditions Over the recommended operating temperature range of –40 °C to 125 °C (unless otherwise noted) (1) MIN VIN to PGND MAX UNIT 3.8 36 EN (2) 0 VIN PG(2) 0 18 Adjustable output voltage VOUT (3) 1 24 V Output current IOUT 0 3 A Input voltage (1) (2) (3) V Recommended operating conditions indicate conditions for which the device is intended to be functional, but do not ensure specific performance limits. For ensured specifications, see Section 6.5. The voltage on this pin must not exceed the voltage on the VIN pin by more than 0.3 V. The maximum output voltage can be extended to 95% of VIN; contact TI for details. Under no conditions should the output voltage be allowed to fall below zero volts. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 5 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 6.4 Thermal Information The value of RθJA given in this table is only valid for comparison with other packages and can not be used for design purposes. These values were calculated in accordance with JESD 51-7, and simulated on a 4-layer JEDEC board. They do not represent the performance obtained in an actual application. For design information see Maximum Ambient Temperature section. LMR336x0 THERMAL METRIC(1) (2) RNX (VQFN) UNIT 12 PINS 72.5(2) °C/W Junction-to-case (top) thermal resistance 35.9 °C/W RθJB Junction-to-board thermal resistance 23.3 °C/W ψJT Junction-to-top characterization parameter 0.8 °C/W ψJB Junction-to-board characterization parameter 23.5 °C/W RθJC(bot) Junction-to-case (bottom) thermal resistance N/A °C/W RθJA Junction-to-ambient thermal resistance RθJC(top) (1) (2) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report. The value of RθJA given in this table is only valid for comparison with other packages and can not be used for design purposes. These values were calculated in accordance with JESD 51-7, and simulated on a 4-layer JEDEC board. They do not represent the performance obtained in an actual application. For design information see Maximum Ambient Temperature section. 6.5 Electrical Characteristics Limits apply over the operating junction temperature (TJ) range of –40°C to +125°C, unless otherwise stated. Minimum and maximum limits are specified through test, design or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise stated, the following conditions apply: VIN = 12 V, VEN = 4 V. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT SUPPLY VOLTAGE VIN Minimum operating input voltage IQ Non-switching input current; measured at VIN pin (2) VFB = 1.2 V ISD Shutdown quiescent current; measured at VIN pin EN = 0 VEN-VCC-H EN input level required to turn on internal LDO Rising threshold VEN-VCC-L EN input level required to turn off internal LDO Falling threshold 0.3 VEN-H EN input level required to start Rising threshold switching 1.2 VEN-HYS Hysteresis below VEN-H Hysteresis below VEN-H; falling 100 mV ILKG-EN Enable input leakage current VEN = 3.3 V 0.2 nA 3.8 V 24 34 µA 5 10 µA 1 V ENABLE V 1.231 1.26 V INTERNAL SUPPLIES VCC Internal LDO output voltage appearing at the VCC pin VBOOT-UVLO Bootstrap voltage undervoltage lock-out threshold(3) 6 V ≤ VIN ≤ 36 V 4.75 5 5.25 2.2 V V VOLTAGE REFERENCE (FB PIN) VFB Feedback voltage; ADJ option IFB Current into FB pin; ADJ option 0.985 FB = 1 V ISC High-side current limit LMR33630 3.85 ILIMIT Low-side current limit LMR33630 2.9 IPEAK-MIN Minimum peak inductor current LMR33630 1 1.015 V 0.2 50 nA 4.5 5.05 A 3.5 4.1 A CURRENT LIMITS(4) 6 Submit Document Feedback 0.69 A Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 Limits apply over the operating junction temperature (TJ) range of –40°C to +125°C, unless otherwise stated. Minimum and maximum limits are specified through test, design or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise stated, the following conditions apply: VIN = 12 V, VEN = 4 V. PARAMETER IZC TEST CONDITIONS MIN Zero current detector threshold TYP MAX -0.106 UNIT A SOFT START tSS Internal soft-start time 2.9 4 6 ms POWER GOOD (PG PIN) VPG-HIGH-UP Power-good upper threshold rising % of FB voltage 105% 107% 110% VPG-HIGH-DN Power-good upper threshold falling % of FB voltage 103% 105% 108% VPG-LOW-UP Power-good lower threshold rising % of FB voltage 92% 94% 97% VPG-LOW-DN Power-good lower threshold falling % of FB voltage 90% 92% 95% tPG Power-good glitch filter delay(1) RPG Power-good flag RDSON VIN-PG Minimum input voltage for proper PG function 50-µA, EN = 0 V VPG PG logic low output 50-µA, EN = 0 V, VIN = 2V ƒSW Switching frequency "A" Version 340 400 460 kHz ƒSW Switching frequency "B" Version 1.2 1.4 1.6 MHz ƒSW Switching frequency "C" Version, RNX package 1.8 2.1 2.3 MHz 60 170 VIN = 12 V, VEN = 4 V 76 150 VEN = 0 V 35 60 µs Ω 2 V 0.2 V OSCILLATOR Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 7 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 Limits apply over the operating junction temperature (TJ) range of –40°C to +125°C, unless otherwise stated. Minimum and maximum limits are specified through test, design or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise stated, the following conditions apply: VIN = 12 V, VEN = 4 V. PARAMETER TEST CONDITIONS MIN TYP MAX UNIT MOSFETS RDS-ON-HS High-side MOSFET ONresistance RNX package 75 145 mΩ RDS-ON-LS Low-side MOSFET ONresistance RNX package 50 95 mΩ (1) (2) (3) (4) See Power-Good Flag Output for details. This is the current used by the device open loop. It does not represent the total input current of the system when in regulation. When the voltage across the CBOOT capacitor falls below this voltage, the low side MOSFET is turned on to recharge CBOOT. The current limit values in this table are tested, open loop, in production. They may differ from those found in a closed loop application. 6.6 Timing Characteristics Limits apply over the operating junction temperature (TJ) range of –40°C to +125°C, unless otherwise stated. Minimum and maximum limits are specified through test, design or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C, and are provided for reference purposes only. Unless otherwise stated, the following conditions apply: VIN = 12 V, VEN = 4 V. MIN 8 NOM MAX UNIT tON-MIN Minimum switch on-time RNX package 68 80 tOFF-MIN Minimum switch off-time RNX package 52 70 ns tON-MAX Maximum switch on-time 7 9 µs Submit Document Feedback ns Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 6.7 System Characteristics The following specifications apply to a typical applications circuit, with nominal component values. Specifications in the typical (TYP) column apply to TJ = 25°C only. Specifications in the minimum (MIN) and maximum (MAX) columns apply to the case of typical components over the temperature range of TJ = –40°C to 125°C. These specifications are not ensured by production testing. PARAMETER VIN Operating input voltage range Output voltage regulation for VOUT = 5 V(1) VOUT Output voltage regulation for VOUT = 3.3 V(1) TEST CONDITIONS VOUT = 3.3 V, IOUT= 0 A MIN TYP MAX 3.8 36 VOUT = 5 V, VIN = 7 V to 36 V, IOUT = 0 A to max. load –1.5% 2.5% VOUT = 5 V, VIN = 7 V to 36 V, IOUT = 1 A to max. load –1.5% 1.5% VOUT = 3.3 V, VIN = 3.8 V to 36 V, IOUT = 0 A to max. load –1.5% 2.5% VOUT = 3.3 V, VIN = 3.8 V to 36 V, IOUT = 1 A to max. load –1.5% 1.5% UNIT V ISUPPLY Input supply current when in regulation VIN = 12 V, VOUT = 3.3 V, IOUT = 0 A, RFBT = 1 MΩ VDROP Dropout voltage; (VIN – VOUT) DMAX Maximum switch duty cycle(2) VHC FB pin voltage required to trip short-circuit hiccup mode 0.4 V tHC Time between current-limit hiccup burst 94 ms tD Switch voltage dead time TSD (1) (2) Thermal shutdown temperature 25 µA VOUT = 5 V, IOUT = 1A Dropout at –1% of regulation, ƒSW = 140 kHz 150 mV VIN = VOUT = 12 V, IOUT = 1 A 98% 2 ns Shutdown temperature 165 °C Recovery temperature 148 °C Deviation is with respect to VIN =12 V, IOUT = 1 A. In dropout the switching frequency drops to increase the effective duty cycle. The lowest frequency is clamped at approximately: ƒMIN = 1 / (tON-MAX + tOFF-MIN). DMAX = tON-MAX /(tON-MAX + tOFF-MIN). Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 9 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 6.8 Typical Characteristics Unless otherwise specified the following conditions apply: TA = 25°C and VIN = 12 V 36 12 11 10 Shutdown Current (µA) Quiescent Current (µA) 34 32 30 28 26 -40C 24 9 8 7 6 5 4 25C 22 5 10 15 20 25 30 35 -40C 2 25C 1 125C 20 0 3 Input Voltage (V) 125C 0 0 40 5 10 15 25 30 35 40 Input Voltage (V) C005 C003 EN = 0 V VFB = 1.2 V Figure 6-2. Shutdown Supply Current Figure 6-1. Non-Switching Input Supply Current 1000 Short Circuit Output Current (mA) 20 1.35 1.30 EN Threshold Voltage (V) 900 800 700 -40C 600 25C 1.25 1.20 1.15 1.10 UP 1.05 DN 125C 500 0 1.00 5 10 15 20 25 30 35 40 Input Voltage (V) VOUT = 0 V ƒS = 400 kHz ±40 ±20 0 20 40 60 80 100 120 Temperature (C) C004 140 C006 See Figure 8-29 Figure 6-3. Short-Circuit Output Current Figure 6-4. Precision Enable Thresholds 1,200 OUTPUT VOLTAGE (0.8V/Div) Peak Inductor Current (mA) 1,100 1,000 900 800 700 25C 500 DN 125C UP 400 5 10 15 20 25 30 Input Voltage (V) 0 INPUT VOLTAGE (1V/Div) IOUT = 1 mA See Figure 8-29 IOUT = 0 A ƒSW = 400 kHz Figure 6-5. UVLO Thresholds 10 -40C 600 Submit Document Feedback VOUT = 5 V 35 40 C006 See Figure 8-29 Figure 6-6. IPEAK-MIN Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 7 Detailed Description 7.1 Overview The LMR33630-Q1 is a synchronous peak-current-mode buck regulator designed for a wide variety of applications. Advanced high speed circuitry allows the device to regulate from an input voltage of 20 V, while providing an output voltage of 3.3 V at a switching frequency of 2.1 MHz. The innovative architecture allows the device to regulate a 3.3-V output from an input of only 3.8 V. The regulator automatically switches modes between PFM and PWM depending on load. At heavy loads, the device operates in PWM at a constant switching frequency. At light loads, the mode changes to PFM with diode emulation allowing DCM. This reduces the input supply current and keeps efficiency high. The device features internal loop compensation which reduces design time and requires fewer external components than externally compensated regulators. The LMR33630-Q1 is available in an ultra-miniature VQFN package with wettable flanks. This package features extremely small parasitic inductance and resistance, enabling very high efficiency while minimizing switch node ringing and dramatically reducing EMI. The VIN/PGND pin layout is symmetrical on either side of the VQFN package. This allows the input current magnetic fields to partially cancel, resulting in reduce EMI generation. 7.2 Functional Block Diagram VCC INT. REG. BIAS OSCILLATOR EN VIN ENABLE LOGIC BOOT HS CURRENT SENSE 1.0V Reference ERROR AMPLIFIER FB + - PG + - PWM COMP. CONTROL LOGIC PFM MODE CONTROL SW DRIVER LS CURRENT SENSE POWER GOOD CONTROL AGND PGND Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 11 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 7.3 Feature Description 7.3.1 Power-Good Flag Output The power-good flag function (PG output pin) of the LMR33630-Q1 can be used to reset a system microprocessor whenever the output voltage is out of regulation. This open-drain output goes low under fault conditions, such as current limit and thermal shutdown, as well as during normal start-up. A glitch filter prevents false flag operation for short excursions of the output voltage, such as during line and load transients. The timing parameters of the glitch filter are found in Section 6.5. Output voltage excursions lasting less than tPG do not trip the power-good flag. Power-good operation can best be understood by reference to Figure 7-1 and Figure 7-2. Note that during initial power up, a delay of about 4 ms (typical) is inserted from the time that EN is asserted to the time that the power-good flag goes high. This delay only occurs during start-up and is not encountered during normal operation of the power-good function. The power-good output consists of an open-drain NMOS, requiring an external pullup resistor to a suitable logic supply. It can also be pulled up to either VCC or VOUT, through a 100-kΩ resistor, as desired. If this function is not needed, the PG pin must be left floating. When EN is pulled low, the flag output is also forced low. With EN low, power good remains valid as long as the input voltage is ≥ 2 V (typical). Limit the current into the power-good flag pin to less than 5 mA D.C. The maximum current is internally limited to about 35 mA when the device is enabled and about 65 mA when the device is disabled. The internal current limit protects the device from any transient currents that can occur when discharging a filter capacitor connected to this output. VOUT VPG-HIGH_UP (107%) VPG-HIGH-DN (105%) VPG-LOW-UP (95%) VPG-LOW-DN (93%) PG High = Power Good Low = Fault Figure 7-1. Static Power-Good Operation 12 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 Glitches do not cause false operation nor reset timer VOUT VPG-LOW-UP (95%) VPG-LOW-DN (93%) < tPG PG tPG tPG tPG Figure 7-2. Power-Good-Timing Behavior 7.3.2 Enable and Start-up Start-up and shutdown are controlled by the EN input. This input features precision thresholds, allowing the use of an external voltage divider to provide an adjustable input UVLO (see Section 8.2.2.10). Applying a voltage of ≥ VEN-VCC_H causes the device to enter standby mode, powering the internal VCC, but not producing an output voltage. Increasing the EN voltage to VEN-H fully enables the device, allowing it to enter start-up mode and start the soft-start period. When the EN input is brought below VEN-H by VEN-HYS, the regulator stops running and enters standby mode. Further decrease in the EN voltage to below VEN-VCC-L completely shuts down the device. This behavior is shown in Figure 7-3. The EN input can be connected directly to VIN if this feature is not needed. This input must not be allowed to float. The values for the various EN thresholds can be found in Section 6.5. The LMR33630-Q1 uses a reference-based soft start that prevents output voltage overshoots and large inrush currents as the regulator is starting up. A typical start-up waveform is shown in Figure 7-4, indicating typical timings. The rise time of the output voltage is about 4 ms (see the Section 6.5). Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 13 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 EN VEN-H VEN-H ± VEN-HYS VEN-VCC-H VEN-VCC-L VCC 5V 0 VOUT VOUT 0 Figure 7-3. Precision Enable Behavior EN, 3V/Div VOUT, 2V/Div PG, 5V/Div Inductor Current, 3A/Div 2ms/Div Figure 7-4. Typical Start-up Behavior VIN = 12 V, VOUT = 5 V, IOUT = 3 A 7.3.3 Current Limit and Short Circuit The LMR33630-Q1 incorporates both peak and valley inductor current limit to provide protection to the device from overloads and short circuits and limit the maximum output current. Valley current limit prevents inductor current runaway during short circuits on the output, while both peak and valley limits work together to limit the maximum output current of the converter. Cycle-by-cycle current limit is used for overloads, while hiccup mode is used for sustained short circuits. Finally, a zero current detector is used on the low-side power MOSFET to implement DEM at light loads (see the Glossary). The typical value of this current limit is found under IZC in Section 6.5. When the device is overloaded, the valley of the inductor current may not reach below ILIMIT (see Section 6.5) before the next clock cycle. When this occurs, the valley current limit control skips that cycle, causing the switching frequency to drop. Further overload causes the switching frequency to continue to drop, and the inductor ripple current to increase. When the peak of the inductor current reaches the high-side current limit, ISC 14 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 (see Section 6.5), the switch duty cycle is reduced and the output voltage falls out of regulation. This represents the maximum output current from the converter and is given approximately by Equation 1. IOUT max ILIMIT ISC 2 (1) If, during current limit, the voltage on the FB input falls below about 0.4 V due to a short circuit, the device enters into hiccup mode. In this mode, the device stops switching for tHC (see Section 6.7), or about 94 ms and then goes through a normal re-start with soft start. If the short-circuit condition remains, the device runs in current limit for about 20 ms (typical) and then shuts down again. This cycle repeats, as shown in Figure 7-5 as long as the short-circuit-condition persists. This mode of operation helps reduce the temperature rise of the device during a hard short on the output. The output current is greatly reduced during hiccup mode. Once the output short is removed and the hiccup delay is passed, the output voltage recovers normally as shown in Figure 7-6. Short triggered Short Released Output Voltage 2V/div Inductor Curent 2A/ Inductor Curent 1A/ 50ms/div 50ms/div Figure 7-5. Inductor Current Burst in Short-Circuit Mode Figure 7-6. Short-Circuit Transient and Recovery 7.3.4 Undervoltage Lockout and Thermal Shutdown The LMR33630-Q1 incorporates an undervoltage-lockout feature on the output of the internal LDO (at the VCC pin). When VCC reaches about 3.7 V, the device is ready to receive an EN signal and start up. When VCC falls below about 3 V, the device shuts down, regardless of EN status. Because the LDO is in dropout during these transitions, the above values roughly represent the input voltage levels during the transitions. Thermal shutdown is provided to protect the regulator from excessive junction temperature. When the junction temperature reaches about 165°C, the device shuts down; re-start occurs when the temperature falls to about 148°C. 7.4 Device Functional Modes 7.4.1 Auto Mode In auto mode, the device moves between PWM and PFM as the load changes. At light loads, the regulator operates in PFM. At higher loads, the mode changes to PWM. The load current for which the device moves from PFM to PWM can be found in Section 8.2.3. The output current at which the device changes modes depends on the input voltage, inductor value, and the nominal switching frequency. For output currents above the curve, the device is in PWM mode. For currents below the curve, the device is in PFM. The curves apply for a nominal switching frequency of 400 kHz and the BOM shown in Table 8-3. At higher switching frequencies, the load at which the mode change occurs is greater. For applications where the switching frequency must be known for a given condition, the transition between PFM and PWM must be carefully tested before the design is finalized. In PWM mode, the regulator operates as a constant frequency converter using PWM to regulate the output voltage. While operating in this mode, the output voltage is regulated by switching at a constant frequency and Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 15 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 modulating the duty cycle to control the power to the load. This provides excellent line and load regulation and low output voltage ripple. In PFM, the high-side MOSFET is turned on in a burst of one or more pulses to provide energy to the load. The duration of the burst depends on how long it takes the inductor current to reach IPEAK-MIN. The periodicity of these bursts is adjusted to regulate the output, while diode emulation (DEM) is used to maximize efficiency (see the Glossary). This mode provides high light-load efficiency by reducing the amount of input supply current required to regulate the output voltage at light loads. PFM results in very good light-load efficiency, but also yields larger output voltage ripple and variable switching frequency. Also, a small increase in output voltage occurs at light loads. The actual switching frequency and output voltage ripple depends on the input voltage, output voltage, and load. Typical switching waveforms in PFM and PWM are shown in Figure 7-7 and Figure 7-8. See Section 8.2.3 for output voltage variation with load in auto mode. SW, 5V/Div SW, 5V/Div VOUT, 10mV/Div VOUT, 10mV/Div Inductor Current, 0.5A/Div Inductor Current, 2A/Div 50µs/Div 2µs/Div Figure 7-7. Typical PFM Switching Waveforms VIN = Figure 7-8. Typical PWM Switching Waveforms VIN = 12 V, VOUT = 5 V, IOUT = 3 A, ƒS = 400 kHz 12 V, VOUT = 5 V, IOUT = 10 mA 7.4.2 Dropout The dropout performance of any buck regulator is affected by the RDSON of the power MOSFETs, the DC resistance of the inductor, and the maximum duty cycle that the controller can achieve. As the input voltage level approaches the output voltage, the off-time of the high-side MOSFET starts to approach the minimum value (see Section 6.6). Beyond this point, the switching can become erratic, and the output voltage falls out of regulation. To avoid this problem, the LMR33630-Q1 automatically reduces the switching frequency to increase the effective duty cycle and maintain regulation. In this data sheet, the dropout voltage is defined as the difference between the input and output voltage when the output has dropped by 1% of its nominal value. Under this condition, the switching frequency has dropped to its minimum value of about 140 kHz. Note that the 0.4 V short circuit detection threshold is not activated when in dropout mode. Typical dropout characteristics can be found in Figure 7-9, Figure 7-10, Figure 7-11, and Figure 7-12. 16 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 6 0.45 0.4 Drop-Out Voltage (V) Output Voltage (V) 5.5 5 4.5 1A 4 2A 3.5 3A 0.35 0.3 0.25 0.2 0.15 0.1 5V 0.05 0A 3.3V 3 0 4 4.5 5 5.5 6 6.5 7 Input Voltage (V) 0.5 1 2.4 2.2 2.2 Switching Frequency (MHz) 1.8 1.6 1.4 1.2 1 0.8 0.6 1A 0.4 2A 0.2 2 2.5 3 C011 2 1.8 1.6 1.4 1.2 1 0.8 0.6 1A 0.4 2A 0.2 3A 0 3.5 Figure 7-10. Typical Dropout Voltage versus Output Current in Frequency Foldback ƒSW = 140 kHz 2.4 2 1.5 Output Current (A) C017 Figure 7-9. Overall Dropout Characteristic VOUT = 5 V Switching Frequency (MHz) 0 3A 0 3.5 4 4.5 5 5.5 6 6.5 Input Voltage (V) 7 7.5 8 3.5 4 5 5.5 6 6.5 7 7.5 Input Voltage (V) C026 Figure 7-11. Typical Switching Frequency in Dropout Mode VOUT = 3.3 V, fSW = 2.1 MHz 4.5 8 8.5 9 9.5 10 C025 Figure 7-12. Typical Switching Frequency in Dropout Mode VOUT = 5 V, fSW = 2.1 MHz 7.4.3 Minimum Switch On-Time Every switching regulator has a minimum controllable on-time dictated by the inherent delays and blanking times associated with the control circuits. This imposes a minimum switch duty cycle and, therefore, a minimum conversion ratio. The constraint is encountered at high input voltages and low output voltages. To help extend the minimum controllable duty cycle, the LMR33630-Q1 automatically reduces the switching frequency when the minimum on-time limit is reached. This way the converter can regulate the lowest programmable output voltage at the maximum input voltage. An estimate for the approximate input voltage, for a given output voltage, before frequency foldback occurs is found in Equation 2. The values of tON and fSW can be found in Section 6.5. As the input voltage is increased, the switch on-time (duty-cycle) reduces to regulate the output voltage. When the on-time reaches the limit, the switching frequency drops, while the on-time remains fixed. This relationship is highlighted in Figure 7-13 for a nominal switching frequency of 2.1 MHz. VIN d VOUT t ON ˜ fSW (2) Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 17 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 2.6 Switching Frequency (MHz) 2.4 2.2 2 1.8 1.6 1.4 1.2 1A 2A 3A 1 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 Input Voltage (V) C024 Figure 7-13. Switching Frequency versus Input Voltage VOUT = 3.3 V 18 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 8 Application and Implementation Note Information in the following applications sections is not part of the TI component specification, and TI does not warrant its accuracy or completeness. TI’s customers are responsible for determining suitability of components for their purposes. Customers should validate and test their design implementation to confirm system functionality. 8.1 Application Information The LMR33630-Q1 step-down DC-to-DC converter is typically used to convert a higher DC voltage to a lower DC voltage with a maximum output current of 3 A. The following design procedure can be used to select components for the LMR33630-Q1. Alternately, the WEBENCH Design Tool can be used to generate a complete design. This tool utilizes an iterative design procedure and has access to a comprehensive database of components. This allows the tool to create an optimized design and allows the user to experiment with various options. Note In this data sheet, the effective value of capacitance is defined as the actual capacitance under D.C. bias and temperature; not the rated or nameplate values. Use high-quality, low-ESR, ceramic capacitors with an X5R or better dielectric throughout. All high value ceramic capacitors have a large voltage coefficient in addition to normal tolerances and temperature effects. Under D.C. bias the capacitance drops considerably. Large case sizes and/or higher voltage ratings are better in this regard. To help mitigate these effects, multiple capacitors can be used in parallel to bring the minimum effective capacitance up to the required value. This can also ease the RMS current requirements on a single capacitor. A careful study of bias and temperature variation of any capacitor bank should be made in order to ensure that the minimum value of effective capacitance is provided. 8.2 Typical Application Figure 8-1 shows a typical application circuit for the LMR33630-Q1. This device is designed to function over a wide range of external components and system parameters. However, the internal compensation is optimized for a certain range of external inductance and output capacitance. As a quick start guide, Figure 8-1 provide typical component values for a range of the most common output voltages. The values given in the table are typical. Other values can be used to enhance certain performance criterion as required by the application. Note that for the VQFN package, the input capacitors are split and placed on either side of the package; see Section 8.2.2.6 for more details. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 19 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 L VIN 6 V to 36 V VOUT SW VIN 5V 3A 8 µH CIN CHF 10 µF CBOOT 220 nF COUT BOOT EN 4x 22 µF 0.1 µF RFBT CFF PG 100 NŸ PG 100 NŸ VCC CVCC 1 µF FB PGND AGND RFBB 24.9 NŸ Figure 8-1. Example Application Circuit (400 kHz) 8.2.1 Design Requirements Table 8-1 provides the parameters for our detailed design procedure example: Table 8-1. Detailed Design Parameters DESIGN PARAMETER EXAMPLE VALUE Input voltage 12 V (6 V to 36 V) Output voltage 5V Maximum output current 0 A to 3 A Switching frequency 400 kHz Table 8-2. Typical External Component Values ƒSW (kHz) VOUT (V) COUT (RATED L (µH) CAPACITANC E) RFBT (Ω) RFBB (Ω) CIN + CHF CBOOT CVCC CFF 400 3.3 6.8 4 × 22 µF 100 k 43.2 k 10 µF + 220 nF 100 nF 1 µF open 1400 3.3 2.2 2 × 22 µF 100 k 43.2 k 10 µF + 220 nF 100 nF 1 µF open 2100 3.3 1.2 2 × 22 µF 100 k 43.2 k 10 µF + 220 nF 100 nF 1 µF open 400 5 8 4 × 22 µF 100 k 24.9 k 10 µF + 220 nF 100 nF 1 µF open 1400 5 2.2 2 × 22 µF 100 k 24.9 k 10 µF + 220 nF 100 nF 1 µF open 2100 5 1.5 2 × 22 µF 100 k 24.9 k 10 µF + 220 nF 100 nF 1 µF open 400 12 15 4 × 22 µF 100 k 9.09 k 10 µF + 220 nF 100 nF 1 µF open 1400 12 4.7 4 × 10 µF 100 k 9.09 k 10 µF + 220 nF 100 nF 1 µF open 2100 12 3.3 4 × 10 µF 100 k 9.09 k 10 µF + 220 nF 100 nF 1 µF open 8.2.2 Detailed Design Procedure The following design procedure applies to Figure 8-1 and Table 8-1. 8.2.2.1 Custom Design With WEBENCH® Tools Click here to create a custom design using the LMR33630-Q1 device with the WEBENCH® Power Designer. 1. Start by entering the input voltage (VIN), output voltage (VOUT), and output current (IOUT) requirements. 2. Optimize the design for key parameters such as efficiency, footprint, and cost using the optimizer dial. 3. Compare the generated design with other possible solutions from Texas Instruments. 20 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 The WEBENCH Power Designer provides a customized schematic along with a list of materials with real-time pricing and component availability. In most cases, these actions are available: • Run electrical simulations to see important waveforms and circuit performance • Run thermal simulations to understand board thermal performance • Export customized schematic and layout into popular CAD formats • Print PDF reports for the design, and share the design with colleagues Get more information about WEBENCH tools at www.ti.com/WEBENCH. 8.2.2.2 Choosing the Switching Frequency The choice of switching frequency is a compromise between conversion efficiency and overall solution size. Lower switching frequency implies reduced switching losses and usually results in higher system efficiency. However, higher switching frequency allows the use of smaller inductors and output capacitors, and hence a more compact design. For this example, 400 kHz was chosen. 8.2.2.3 Setting the Output Voltage The output voltage of the LMR33630-Q1 is externally adjustable using a resistor divider network. The range of recommended output voltage is found in Section 6.3. The divider network is comprised of RFBT and RFBB, and closes the loop between the output voltage and the converter. The converter regulates the output voltage by holding the voltage on the FB pin equal to the internal reference voltage, VREF. The resistance of the divider is a compromise between excessive noise pick-up and excessive loading of the output. Smaller values of resistance reduce noise sensitivity but also reduce the light-load efficiency. The recommended value for RFBT is 100 kΩ; with a maximum value of 1 MΩ. If a 1 MΩ is selected for RFBT, then a feedforward capacitor must be used across this resistor to provide adequate loop phase margin (see Section 8.2.2.9). Once RFBT is selected, Equation 3 is used to select RFBB. VREF is nominally 1 V (see Section 6.5 for limits). RFBB RFBT ª VOUT « ¬ VREF º 1» ¼ (3) For this 5-V example, RFBT = 100 kΩ and RFBB = 24.9 kΩ are chosen. 8.2.2.4 Inductor Selection The parameters for selecting the inductor are the inductance and saturation current. The inductance is based on the desired peak-to-peak ripple current and is normally chosen to be in the range of 20% to 40% of the maximum output current. Experience shows that the best value for inductor ripple current is 30% of the maximum load current. Note that when selecting the ripple current for applications with much smaller maximum load than the maximum available from the device, the maximum device current should be used. Equation 4 can be used to determine the value of inductance. The constant K is the percentage of inductor current ripple. For this example, K = 0.3 was chosen and an inductance L = 8.1 µH was found; the next standard value of 8 µH was selected. L VIN VOUT V ˜ OUT fSW ˜ K ˜ IOUT max VIN (4) Ideally, the saturation current rating of the inductor must be at least as large as the high-side switch current limit, ISC (see Section 6.5). This ensures that the inductor does not saturate even during a short circuit on the output. When the inductor core material saturates, the inductance falls to a very low value, causing the inductor current to rise very rapidly. Although the valley current limit, ILIMIT, is designed to reduce the risk of current run-away, a saturated inductor can cause the current to rise to high values very rapidly. This can lead to component damage; do not allow the inductor to saturate. Inductors with a ferrite core material have very hard saturation characteristics, but usually have lower core losses than powdered iron cores. Powered iron cores exhibit a soft saturation, allowing for some relaxation in the current rating of the inductor. However, they have Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 21 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 more core losses at frequencies typically above 1 MHz. In any case, the inductor saturation current must not be less than the device low-side current limit, ILIMIT (see the Section 6.5). The maximum inductance is limited by the minimum current ripple required for the current mode control to perform correctly. As a rule-of-thumb, the minimum inductor ripple current must be no less than about 10% of the device maximum rated current under nominal conditions. LMIN t 0.28 ˜ VOUT fSW (5) 8.2.2.5 Output Capacitor Selection The value of the output capacitor and the ESR of the capacitor determine the output voltage ripple and load transient performance. The output capacitor bank is usually limited by the load transient requirements, rather than the output voltage ripple. Equation 6 can be used to estimate a lower bound on the total output capacitance and an upper bound on the ESR, which is required to meet a specified load transient. COUT t ESR d D fSW 'IOUT ˜ 'VOUT ˜ K º K2 ˜ 2 D» 12 »¼ ª ˜«1 D ˜ 1 K «¬ 2 K ˜ 'VOUT ª 2 ˜ 'IOUT «1 K «¬ K2 12 § 1 ·º ¸¸» ˜ ¨¨1 © (1 D) ¹»¼ VOUT VIN (6) where • • • ΔVOUT = output voltage transient ΔIOUT = output current transient K = ripple factor from Section 8.2.2.4 Once the output capacitor and ESR have been calculated, Equation 7 can be used to check the peak-to-peak output voltage ripple; Vr. Vr # 'IL ˜ ESR 2 1 8 ˜ fSW ˜ COUT 2 (7) The output capacitor and ESR can then be adjusted to meet both the load transient and output ripple requirements. For this example, a ΔVOUT ≤ 250 mV for an output current step of ΔIOUT = 2 A is required. Equation 6 gives a minimum value of 52 µF and a maximum ESR of 0.11 Ω. Assuming a 20% tolerance and a 10% bias de-rating, you arrive at a minimum capacitance of 72 µF. This can be achieved with a bank of 4 × 22-µF, 16-V ceramic capacitors in the 1210 case size. More output capacitance can be used to improve the load transient response. Ceramic capacitors can easily meet the minimum ESR requirements. In some cases, an aluminum electrolytic capacitor can be placed in parallel with the ceramics to help build up the required value of capacitance. In general, use a capacitor of at least 10 V for output voltages of 3.3 V or less and a capacitor of 16 V or more for output voltages of 5 V and above. In practice, the output capacitor has the most influence on the transient response and loop phase margin. Load transient testing and Bode plots are the best way to validate any given design and must always be completed before the application goes into production. In addition to the required output capacitance, a small ceramic placed on the output can help reduce high frequency noise. Small case size ceramic capacitors in the range 22 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 of 1 nF to 100 nF can be very helpful in reducing voltage spikes on the output caused by inductor and board parasitics. The maximum value of total output capacitance must be limited to about 10 times the design value, or 1000 µF, whichever is smaller. Large values of output capacitance can adversely affect the start-up behavior of the regulator as well as the loop stability. If values larger than noted here must be used, then a careful study of start-up at full load and loop stability must be performed. 8.2.2.6 Input Capacitor Selection The ceramic input capacitors provide a low impedance source to the regulator in addition to supplying the ripple current and isolating switching noise from other circuits. A minimum of 10 µF of ceramic capacitance is required on the input of the LMR33630-Q1. This must be rated for at least the maximum input voltage that the application requires; preferably twice the maximum input voltage. This capacitance can be increased to help reduce input voltage ripple and maintain the input voltage during load transients. In addition, a small case size, 220-nF ceramic capacitor must be used at the input, as close as possible to the regulator. This provides a high frequency bypass for the control circuits internal to the device. For this example, a 4.7-µF, 50-V, X7R (or better) ceramic capacitor is chosen. The 220 nF must also be rated at 50 V with an X7R dielectric. The VQFN (RNX) package provides two input voltage pins and two power ground pins on opposite sides of the package. This allows the input capacitors to be split, and placed optimally with respect to the internal power MOSFETs, thus improving the effectiveness of the input bypassing. In this example, a single 4.7-µF and two 100-nF ceramic capacitors at each VIN/PGND location. Many times, it is desirable to use an electrolytic capacitor on the input in parallel with the ceramics. This is especially true if long leads/traces are used to connect the input supply to the regulator. The moderate ESR of this capacitor can help damp any ringing on the input supply caused by the long power leads. The use of this additional capacitor also helps with momentary voltage dips caused by input supplies with unusually high impedance. Most of the input switching current passes through the ceramic input capacitor or capacitors. The approximate worst case RMS value of this current can be calculated from Equation 8 and must be checked against the manufacturers' maximum ratings. IRMS # IOUT 2 (8) 8.2.2.7 CBOOT The LMR33630-Q1 requires a bootstrap capacitor connected between the BOOT pin and the SW pin. This capacitor stores energy that is used to supply the gate drivers for the power MOSFETs. A high-quality ceramic capacitor of 100 nF and at least 10 V is required. 8.2.2.8 VCC The VCC pin is the output of the internal LDO used to supply the control circuits of the regulator. This output requires a 1-µF, 16-V ceramic capacitor connected from VCC to GND for proper operation. In general, avoid loading this output with any external circuitry. However, this output can be used to supply the pullup for the power-good function (see Section 7.3.1). A value of 100 kΩ is a good choice in this case. The nominal output voltage on VCC is 5 V; see Section 6.5 for limits. Do not short this output to ground or any other external voltage. 8.2.2.9 CFF Selection In some cases, a feedforward capacitor can be used across RFBT to improve the load transient response or improve the loop-phase margin. This is especially true when values of RFBT > 100 kΩ are used. Large values of RFBT, in combination with the parasitic capacitance at the FB pin, can create a small signal pole that interferes with the loop stability. A CFF can help to mitigate this effect. Equation 9 can be used to estimate the value of CFF. The value found with Equation 9 is a starting point; use lower values to determine if any advantage is gained by the use of a CFF capacitor. The Optimizing Transient Response of Internally Compensated DC-DC Converters with Feed-forward Capacitor Application Report is helpful when experimenting with a feedforward capacitor. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 23 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 VOUT ˜ COUT CFF 120 ˜ RFBT ˜ VREF VOUT (9) 8.2.2.10 External UVLO In some cases, an input UVLO level different than that provided internal to the device is needed. This can be accomplished by using the circuit shown in Figure 8-2. The input voltage at which the device turns on is designated VON while the turnoff voltage is VOFF. First, a value for RENB is chosen in the range of 10 kΩ to 100 kΩ and then Equation 10 is used to calculate RENT and VOFF. VIN RENT EN RENB Figure 8-2. Setup for External UVLO Application R ENT § V ON ¨¨ © VEN H · 1¸¸ ˜ R ENB ¹ V OFF § V ON ˜ ¨¨ 1 © VEN HYS VEN H · ¸¸ ¹ (10) where • • VON = VIN turnon voltage VOFF = VIN turnoff voltage 8.2.2.11 Maximum Ambient Temperature As with any power conversion device, the LMR33630-Q1 dissipates internal power while operating. The effect of this power dissipation is to raise the internal temperature of the converter above ambient. The internal die temperature (TJ) is a function of the ambient temperature, the power loss, and the effective thermal resistance, RθJA, of the device and PCB combination. The maximum internal die temperature for the LMR33630-Q1 must be limited to 125°C. This establishes a limit on the maximum device power dissipation and therefore the load current. Equation 11 shows the relationships between the important parameters. It is easy to see that larger ambient temperatures (TA) and larger values of RθJA reduce the maximum available output current. The converter efficiency can be estimated by using the curves provided in this data sheet. If the desired operating conditions cannot be found in one of the curves, then interpolation can be used to estimate the efficiency. Alternatively, the EVM can be adjusted to match the desired application requirements and the efficiency can be measured directly. The correct value of RθJA is more difficult to estimate. As stated in the Semiconductor and IC Package Thermal Metrics Application Report, the value of RθJA given in Section 6.4 is not valid for design purposes and must not be used to estimate the thermal performance of the application. The values reported in that table were measured under a specific set of conditions that are rarely obtained in an actual application. IOUT MAX TJ TA 1 K ˜ ˜ R TJA 1 K VOUT (11) where • 24 η = efficiency Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 3.5 65 3 Maximum Output Current (A) 70 60 55 R JA (ƒC/w) The effective RθJA is a critical parameter and depends on many factors such as power dissipation, air temperature/flow, PCB area, copper heat-sink area, number of thermal vias under the package, and adjacent component placement, just to mention just a few. Due to the ultra-miniature size of the VQFN (RNX) package, a DAP is not available. This means that this package exhibits a somewhat large value RθJA. A typical example of RθJA vs copper board area can be found in Figure 8-3. The copper area given in the graph is for each layer; the top and bottom layers are 2 oz. copper each, while the inner layers are 1 oz. A typical curve of maximum output current vs. ambient temperature is shown in Figure 8-4. This data was taken with a device/PCB combination giving an RθJA of about 50°C/W. It must be remembered that the data given in these graphs are for illustration purposes only, and the actual performance in any given application depends on all of the previously mentioned factors. 50 45 2.5 2 1.5 1 0.5 RNX, 4L 40 0 10 20 30 40 Copper Area (cm2) 50 60 70 0 0 10 20 30 40 50 60 70 80 90 100 110 120 130 140 C005 Figure 8-3. RθJA versus Copper Board Area for the VQFN (RNX) Package Ambient Temperature (ƒC) VIN = 12 V ƒSW = 400 kHz C006 VOUT = 5 V RθJA = 50°C/W Figure 8-4. Maximum Output Current versus Ambient Temperature Use the following resources as a guide to optimal thermal PCB design and estimating RθJA for a given application environment: • • • • • • • Thermal Design by Insight not Hindsight A Guide to Board Layout for Best Thermal Resistance for Exposed Pad Packages Semiconductor and IC Package Thermal Metrics Thermal Design Made Simple with LM43603 and LM43602 PowerPAD™ Thermally Enhanced Package PowerPAD™ Made Easy Using New Thermal Metrics Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 25 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 8.2.3 Application Curves 100 100 95 95 90 90 85 85 Efficiency (%) Efficiency (%) Unless otherwise specified the following conditions apply: VIN = 12 V, TA = 25°C. The circuit is shown in Figure 8-29, with the appropriate BOM from Table 8-3. 80 75 70 8V 65 0.01 0.1 1 VOUT = 5 V 400 kHz 12V 24V 36V 50 0.001 10 Output Current (A) 8V 55 36V 50 0.001 70 60 24V 55 75 65 12V 60 80 RNX Package VOUT = 3.3 V 95 90 90 85 85 Efficiency (%) Efficiency (%) 100 95 80 75 70 8V 65 55 1 80 75 70 5V 12V 24V 36V 50 0.001 10 Output Current (A) RNX Package VOUT = 3.3 V 95 90 90 85 85 Efficiency (%) Efficiency (%) 100 80 75 70 8V 65 55 1 80 75 70 8V 12V 24V 10 36V 50 0.001 0.01 RNX Package 0.1 Output Current (A) C010 VOUT = 3.3 V Figure 8-9. Efficiency 26 C020 55 36V 2.1 MHz 10 RNX Package 60 24V VOUT = 5 V 1.4 MHz 65 12V 60 0.1 1 Figure 8-8. Efficiency 95 Output Current (A) 0.1 Output Current (A) 100 0.01 0.01 C019 Figure 8-7. Efficiency 50 0.001 C008 55 36V 1.4 MHz 10 RNX Package 60 24V VOUT = 5 V 400 kHz 65 12V 60 0.1 1 Figure 8-6. Efficiency 100 0.01 0.1 Output Current (A) C007 Figure 8-5. Efficiency 50 0.001 0.01 2.1 MHz 1 10 C009 RNX Package Figure 8-10. Efficiency Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 5.06 32 8V 5.055 Output Voltage (V) Input Supply Current (µA) 12V 5.05 24V 5.045 36V 5.04 5.035 5.03 5.025 5.02 30 28 26 24 22 5.015 5V 5.01 0 0.5 1 1.5 2 2.5 3 20 0 3.5 Output Current (A) 10 15 20 25 30 35 40 Input Voltage (V) C011 VOUT = 5 V VOUT = 5 V Figure 8-11. Line and Load Regulation IOUT = 0 A C017 RFBT = 1 MΩ Figure 8-12. Input Supply Current 0.6 10000 Switching Frequency (kHz) 0.5 Output Current (A) 5 0.4 0.3 9 PWM 0.2 PFM ; 0.1 1000 100 10 8V 1 12V 18V 5V 0 0 5 10 15 20 25 30 35 Input Voltage (V) VOUT = 5 V 0.1 0.00001 40 0.0001 0.01 0.1 1 10 Output Current (A) C012 ƒSW = 400 kHz VOUT = 5 V Figure 8-13. Mode Change Thresholds 0.001 C022 ƒSW = 2100 kHz Figure 8-14. Switching Frequency versus Output Current VOUT, 300mV/Div VOUT, 300mV/Div Output Current, 1A/Div Output Current, 1A/Div 100µs/Div 100µs/Div 0 0 VIN = 12 V tf = tr = 2 µs VOUT = 5 V IOUT = 0 A to 3 A Figure 8-15. Load Transient VIN = 12 V tf = tr = 2 µs VOUT = 5 V IOUT = 1 A to 3 A Figure 8-16. Load Transient Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 27 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 32 3.35 5V 12V 3.34 24V 3.335 36V Input Supply Current (µA) Output Voltage (V) 3.345 3.33 3.325 3.32 3.315 30 28 26 24 22 3.3V 20 0 3.31 0 0.5 1 1.5 2 2.5 3 3.5 Output Current (A) 5 10 15 C011 VOUT = 3.3 V VOUT = 3.3 V 20 25 30 Input Voltage (V) IOUT = 0 A 35 40 C016 RFBT = 1 MΩ Figure 8-18. Input Supply Current Figure 8-17. Line and Load Regulation 0.8 10000 Switching Frequency (kHz) Output Current (A) 0.7 0.6 0.5 0.4 9 PWM 0.3 0.2 PFM ; 0.1 0 0 5 10 15 100 10 5V 1 12V 18V 3.3V 20 25 30 35 Input Voltage (V) VOUT = 3.3 V 1000 0.1 0.00001 40 0.0001 VOUT = 3.3 V A. Figure 8-19. Mode Change Thresholds 0.01 0.1 1 10 Output Current (A) C012 ƒSW = 400 kHz 0.001 C023 ƒSW = 2100 kHz Figure 8-20. Switching Frequency versus Output Current VOUT, 300mV/Div VOUT, 300mV/Div Output Current, 1A/Div Output Current, 1A/Div 100µs/Div 0 VIN = 12 V tf = tr = 2 µs VOUT = 3.3 V IOUT = 0 A to 3 A Figure 8-21. Load Transient 28 100µs/Div 0 VIN = 12 V VOUT = 3.3V tf = tr = 2 µs IOUT = 1 A to 3 A Figure 8-22. Load Transient Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 VIN = 12 V VOUT = 5 V ƒSW = 400 kHz IOUT = 3 A RNX package Figure 8-23. Conducted EMI VIN = 12 V VOUT = 5 V ƒSW = 400 kHz IOUT = 3 A RNX package Figure 8-25. Radiated EMI Biconical Antenna (Vertical) VIN = 12 V VOUT = 5 V ƒSW = 400 kHz IOUT = 3 A RNX package Figure 8-27. Radiated EMI Log-periodic Antenna (Vertical) VIN = 12 V VOUT = 5 V ƒSW = 400 kHz IOUT = 3 A RNX package Figure 8-24. Radiated EMI Biconical Antenna (Horizontal) VIN = 12 V VOUT = 5 V ƒSW = 400 kHz IOUT = 3 A RNX package Figure 8-26. Radiated EMI Log-periodic Antenna (Horizontal) VIN = 12 V VOUT = 5 V ƒSW = 400 kHz IOUT = 3 A RNX package Figure 8-28. Radiated EMI Rod Antenna Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 29 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 L VIN VIN VOUT SW U1 CBOOT CIN CHF COUT BOOT EN 0.1 µF RFBT PG 100 NŸ PG 100 NŸ VCC CVCC 1 µF FB PGND AGND RFBB Figure 8-29. Circuit for Application Curves Table 8-3. BOM for Typical Application Curves RNX Package(1) VOUT (1) FREQUENCY RFBB COUT CIN + CHF L U1 3.3 V 400 kHz 43.3 kΩ 4 × 22 µF 3.3 V 1400 KHz 43.3 kΩ 4 × 22 µF 2 × 4.7 µF + 2 × 100 nF 6.8 µH, 14 mΩ LMR33630ARNX 2 × 4.7 µF + 2 × 100 nF 2.2 µH, 11.4 mΩ LMR33630BRNX 3.3 V 2100 kHz 43.3 kΩ 5V 400 kHz 24.9 kΩ 4 × 22 µF 2 × 4.7 µF + 2 × 100 nF 1.2 µH, 7 mΩ LMR33630CRNX 4 × 22 µF 2 × 4.7 µF + 2 × 100 nF 8 µH, 25 mΩ LMR33630ARNX 5V 1400 KHz 5V 2100 kHz 24.9 kΩ 4 × 22 µF 2 × 4.7 µF + 2 × 100 nF 2.2 µH, 11.4 mΩ LMR33630BRNX 24.9 kΩ 4 × 22 µF 2 × 4.7 µF + 2 × 100 nF 1.5 µH, 8.2 mΩ LMR33630CRNX The values in this table were selected to enhance certain performance criteria and may not represent typical values. + 100µF 0.1µF 4.7µF 3.3µF 2x 0.1µF 3x 4.7µF 2x 0.1µF Input Supply 2x 4.7µF Ferrite Bead Input to Regulator Figure 8-30. Typical Input EMI Filter Filter Used Only for EMI Measurements Found in Application Curves 8.3 What to Do and What Not to Do • • • • • • • 30 Don't: Exceed the Absolute Maximum Ratings. Don't: Exceed the ESD Ratings. Don't: Exceed the Recommended Operating Conditions. Don't: Allow the EN input to float. Don't: Allow the output voltage to exceed the input voltage, nor go below ground. Don't: Use the value of RθJA given in the Thermal Information table to design your application. Use the information in the Maximum Ambient Temperature section. Do: Follow all the guidelines and suggestions found in this data sheet before committing the design to production. TI application engineers are ready to help critique your design and PCB layout to help make your project a success (see Section 11.3). Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 9 Power Supply Recommendations The characteristics of the input supply must be compatible with Section 6.1 and Section 6.3 found in this data sheet. In addition, the input supply must be capable of delivering the required input current to the loaded regulator. The average input current can be estimated with Equation 12, where η is the efficiency. IIN VOUT ˜ IOUT VIN ˜ K (12) If the regulator is connected to the input supply through long wires or PCB traces, special care is required to achieve good performance. The parasitic inductance and resistance of the input cables can have an adverse effect on the operation of the regulator. The parasitic inductance, in combination with the low-ESR, ceramic input capacitors, can form an under damped resonant circuit, resulting in overvoltage transients at the input to the regulator. The parasitic resistance can cause the voltage at the VIN pin to dip whenever a load transient is applied to the output. If the application is operating close to the minimum input voltage, this dip can cause the regulator to momentarily shutdown and reset. The best way to solve these kind of issues is to reduce the distance from the input supply to the regulator and/or use an aluminum or tantalum input capacitor in parallel with the ceramics. The moderate ESR of these types of capacitors help damp the input resonant circuit and reduce any overshoots. A value in the range of 20 µF to 100 µF is usually sufficient to provide input damping and help to hold the input voltage steady during large load transients. Sometimes, for other system considerations, an input filter is used in front of the regulator. This can lead to instability, as well as some of the effects mentioned above, unless it is designed carefully. The user guide AN-2162 Simple Success With Conducted EMI From DCDC Converters provides helpful suggestions when designing an input filter for any switching regulator. In some cases, a transient voltage suppressor (TVS) is used on the input of regulators. One class of this device has a snap-back characteristic (thyristor type). The use of a device with this type of characteristic is not recommended. When the TVS fires, the clamping voltage falls to a very low value. If this voltage is less than the output voltage of the regulator, the output capacitors discharge through the device back to the input. This uncontrolled current flow can damage the device. The input voltage must not be allowed to fall below the output voltage. In this scenario, such as a shorted input test, the output capacitors discharges through the internal parasitic diode found between the VIN and SW pins of the device. During this condition, the current can become uncontrolled, possibly causing damage to the device. If this scenario is considered likely, then a Schottky diode between the input supply and the output should be used. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 31 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 10 Layout 10.1 Layout Guidelines The PCB layout of any DC/DC converter is critical to the optimal performance of the design. Bad PCB layout can disrupt the operation of an otherwise good schematic design. Even if the converter regulates correctly, bad PCB layout can mean the difference between a robust design and one that cannot be mass produced. Furthermore, the EMI performance of the regulator is dependent on the PCB layout, to a great extent. In a buck converter, the most critical PCB feature is the loop formed by the input capacitor or input capacitors, and power ground, as shown in Figure 10-1. This loop carries large transient currents that can cause large transient voltages when reacting with the trace inductance. These unwanted transient voltages will disrupt the proper operation of the converter. Because of this, the traces in this loop must be wide and short, and the loop area as small as possible to reduce the parasitic inductance. Figure 10-2 shows a recommended layout for the critical components of the LMR33630-Q1. 1. Place the input capacitor or capacitors as close as possible to the VIN and GND terminals. VIN and GND pins are adjacent, simplifying the input capacitor placement. With the VQFN package there are two VIN/PGND pairs on either side of the package. This provides for a symmetrical layout and helps minimize switching noise and EMI generation. A wide VIN plane must be used on a lower layer to connect both of the VIN pairs together to the input supply; see the layout example. 2. Place bypass capacitor for VCC close to the VCC pin. This capacitor must be placed close to the device and routed with short, wide traces to the VCC and GND pins. 3. Use wide traces for the CBOOT capacitor. Place CBOOT close to the device with short/wide traces to the BOOT and SW pins. It is important to route the SW connection under the device to the NC pin, and use this path to connect the BOOT capacitor to SW. 4. Place the feedback divider as close as possible to the FB pin of the device. Place RFBB, RFBT, and CFF, if used, physically close to the device. The connections to FB and GND must be short and close to those pins on the device. The connection to VOUT can be somewhat longer. However, this latter trace must not be routed near any noise source (such as the SW node) that can capacitively couple into the feedback path of the regulator. 5. Use at least one ground plane in one of the middle layers. This plane acts as a noise shield and also act as a heat dissipation path. 6. Provide wide paths for VIN, VOUT, and GND. Making these paths as wide and direct as possible reduces any voltage drops on the input or output paths of the converter and maximizes efficiency. 7. Provide enough PCB area for proper heat sinking. As stated in Section 8.2.2.11, enough copper area must be used to ensure a low RθJA, commensurate with the maximum load current and ambient temperature. Make the top and bottom PCB layers with two-ounce copper; and no less than one ounce. If the PCB design uses multiple copper layers (recommended), thermal vias can also be connected to the inner layer heat-spreading ground planes. 8. Keep switch area small. Keep the copper area connecting the SW pin to the inductor as short and wide as possible. At the same time the total area of this node should be minimized to help reduce radiated EMI. See the following PCB layout resources for additional important guidelines: • • • • 32 Layout Guidelines for Switching Power Supplies Simple Switcher PCB Layout Guidelines Construction Your Power Supply- Layout Considerations Low Radiated EMI Layout Made Simple with LM4360x and LM4600x Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 VIN KEEP CURRENT LOOP SMALL CIN SW GND Figure 10-1. Current Loops with Fast Edges 10.1.1 Ground and Thermal Considerations As mentioned above, TI recommends using one of the middle layers as a solid ground plane. A ground plane provides shielding for sensitive circuits and traces. It also provides a quiet reference potential for the control circuitry. The AGND and PGND pins must be connected to the ground planes using vias next to the bypass capacitors. PGND pins are connected directly to the source of the low side MOSFET switch, and also connected directly to the grounds of the input and output capacitors. The PGND net contains noise at the switching frequency and can bounce due to load variations. The PGND trace, as well as the VIN and SW traces, must be constrained to one side of the ground planes. The other side of the ground plane contains much less noise and must be used for sensitive routes. Use as much copper as possible, for system ground plane, on the top and bottom layers for the best heat dissipation. Use a four-layer board with the copper thickness for the four layers, starting from the top as: 2 oz / 1 oz / 1 oz / 2 oz. A four-layer board with enough copper thickness, and proper layout, provides low current conduction impedance, proper shielding, and lower thermal resistance. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 33 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 10.2 Layout Example VOUT VOUT INDUCTOR COUT COUT COUT COUT GND GND CIN CIN CHF 12 11 2 10 3 9 4 8 5 6 VIN EN PGOOD 7 RFBT CBOOT 1 VIN CHF CVCC RFBB GND HEATSINK GND HEATSINK INNER GND PLANE Top Trace/Plane Inner GND Plane VIN Strap on Inner Layer Top VIA to Signal Layer Inner GND Plane VIA to GND Planes VIN Strap and GND Plane VIA to VIN Strap Signal traces and GND Plane Trace on Signal Layer Figure 10-2. Example Layout for VQFN Package 34 Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 11 Device and Documentation Support 11.1 Device Support 11.1.1 Development Support 11.1.1.1 Custom Design With WEBENCH® Tools Click here to create a custom design using the LM33630-Q1 device with the WEBENCH® Power Designer. 1. Start by entering the input voltage (VIN), output voltage (VOUT), and output current (IOUT) requirements. 2. Optimize the design for key parameters such as efficiency, footprint, and cost using the optimizer dial. 3. Compare the generated design with other possible solutions from Texas Instruments. The WEBENCH Power Designer provides a customized schematic along with a list of materials with real-time pricing and component availability. In most cases, these actions are available: • Run electrical simulations to see important waveforms and circuit performance • Run thermal simulations to understand board thermal performance • Export customized schematic and layout into popular CAD formats • Print PDF reports for the design, and share the design with colleagues Get more information about WEBENCH tools at www.ti.com/WEBENCH. 11.2 Documentation Support 11.2.1 Related Documentation For related documentation see the following: • Thermal Design by Insight not Hindsight • A Guide to Board Layout for Best Thermal Resistance for Exposed Pad Packages • Semiconductor and IC Package Thermal Metrics • Thermal Design Made Simple with LM43603 and LM43602 • PowerPADTM Thermally Enhanced Package • PowerPADTM Made Easy • Using New Thermal Metrics • Layout Guidelines for Switching Power Supplies • Simple Switcher PCB Layout Guidelines • Construction Your Power Supply- Layout Considerations • Low Radiated EMI Layout Made Simple with LM4360x and LM4600x 11.3 Support Resources TI E2E™ support forums are an engineer's go-to source for fast, verified answers and design help — straight from the experts. Search existing answers or ask your own question to get the quick design help you need. Linked content is provided "AS IS" by the respective contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of Use. 11.4 Receiving Notification of Documentation Updates To receive notification of documentation updates, navigate to the device product folder on ti.com. Click on Subscribe to updates to register and receive a weekly digest of any product information that has changed. For change details, review the revision history included in any revised document. 11.5 Trademarks HotRod™, PowerPAD™, and TI E2E™ are trademarks of Texas Instruments. WEBENCH® is a registered trademark of Texas Instruments. All trademarks are the property of their respective owners. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 35 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 11.6 Electrostatic Discharge Caution This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. 11.7 Glossary TI Glossary 36 This glossary lists and explains terms, acronyms, and definitions. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 LMR33630-Q1 www.ti.com SNVSB26C – JUNE 2018 – REVISED OCTOBER 2020 Mechanical, Packaging, and Orderable Information The following pages include mechanical, packaging, and orderable information. This information is the most current data available for the designated devices. This data is subject to change without notice and revision of this document. For browser-based versions of this data sheet, refer to the left-hand navigation. Submit Document Feedback Copyright © 2022 Texas Instruments Incorporated Product Folder Links: LMR33630-Q1 37 PACKAGE OPTION ADDENDUM www.ti.com 29-Jan-2022 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Pins Package Drawing Qty Eco Plan (2) Lead finish/ Ball material MSL Peak Temp Op Temp (°C) Device Marking (3) (4/5) (6) LMR33630AQRNXRQ1 ACTIVE VQFN-HR RNX 12 3000 RoHS & Green NIPDAU | SN Level-2-260C-1 YEAR -40 to 125 Z630AQ LMR33630AQRNXTQ1 ACTIVE VQFN-HR RNX 12 250 RoHS & Green NIPDAU | SN Level-2-260C-1 YEAR -40 to 125 Z630AQ LMR33630BQRNXRQ1 ACTIVE VQFN-HR RNX 12 3000 RoHS & Green NIPDAU | SN Level-2-260C-1 YEAR -40 to 125 Z630BQ LMR33630BQRNXTQ1 ACTIVE VQFN-HR RNX 12 250 RoHS & Green NIPDAU | SN Level-2-260C-1 YEAR -40 to 125 Z630BQ LMR33630CQRNXRQ1 ACTIVE VQFN-HR RNX 12 3000 RoHS & Green NIPDAU | SN Level-2-260C-1 YEAR -40 to 125 Z630CQ LMR33630CQRNXTQ1 ACTIVE VQFN-HR RNX 12 250 RoHS & Green NIPDAU | SN Level-2-260C-1 YEAR -40 to 125 Z630CQ (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may reference these types of products as "Pb-Free". RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption. Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of