LM51501QWRUMRQ1

LM51501-Q1 SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 LM51501-Q1 Wide VIN Automotive Low IQ Boost Controller 1 Features 3 Description • The LM51501-Q1 is a wide input range automatic boost controller. The device can be used to maintain a stable output voltage during automotive cranking from a vehicle battery or from a backup battery. • • • • • • • • • • • • • 2 Applications • • • The LM51501-Q1 switching frequency is programmed by a resistor from 220 kHz to 2.3 MHz. Fast switching (≥ 2.2 MHz) minimizes AM band interference and allows for a small solution size and fast transient response. The LM51501-Q1 operates in low IQ standby mode when the input or output voltage is above the preset standby thresholds and automatically wakes up when the output voltage drops below the preset wake-up threshold. The device transitions in and out of low IQ standby mode to extend battery life at light load. A single resistor programs the target output regulation voltage as well as the configuration. Additional features include low shutdown current, boost status indicator, adjustable cycle-by-cycle current limit, and thermal shutdown. A status indicator can be used to control a circuit to bypass the diode when the part is not boosting in order to reduce power dissipation. In E-call mode, the device can be used to control a disconnect switch to protect the backup-battery. Device Information LM51501-Q1 Automotive start-stop system Automotive emergency call system Battery-powered boost converters VSUPPLY PACKAGE(1) PART NUMBER (1) BODY SIZE (NOM) WQFN (16) 4.00 mm × 4.00 mm For all available packages, see the orderable addendum at the end of the data sheet. 100 VLOAD 95 LO VIN CS AGND PGND VOUT EN STATUS Efficiency (%) • AEC-Q100 qualified: – Device temperature grade 1: –40°C to +125°C ambient operating temperature range – Device HBM ESD classification level 2 – Device CDM ESD classification level C4B Functional Safety-Capable – Documentation available to aid functional safety system design Wide VIN input range from 1.5 V to 42 V when VOUT ≥ 5 V (65-V absolute maximum) Low shutdown current (IQ ≤ 5 µA) Low standby current (IQ ≤ 15 µA) Four programmable output voltage options and two selectable configurations – 6.0 V, 6.5 V, 9.5 V, or 11.5 V – Start-stop or e-call configurations Adjustable switching frequency from 220 kHz to 2.3 MHz Automatic wake-up and standby mode transition Optional clock synchronization Boost status indicator 1.5-A peak MOSFET gate driver Adjustable cycle-by-cycle current limit Thermal shutdown 16-pin WQFN with wettable and non-wettable flank options Create a custom design using the LM51501-Q1 with the WEBENCH® Power Designer 90 85 80 VSUPPLY=7.5V VSUPPLY=6.5V VSUPPLY=5.5V VSUPPLY=4.5V VSUPPLY=3.5V LM51501 COMP SYNC RT VSET VCC 75 AVCC 70 0 Typical Application Circuit 0.3 0.6 0.9 1.2 1.5 Load Current (A) 1.8 2.1 2.4 D008 Efficiency (VLOAD = 9.5 V, FSW = 440 kHz) 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. LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Table of Contents 1 Features............................................................................1 2 Applications..................................................................... 1 3 Description.......................................................................1 4 Revision History.............................................................. 2 5 Device Comparison Table...............................................3 6 Pin Configuration and Functions...................................4 7 Specifications.................................................................. 5 7.1 Absolute Maximum Ratings........................................ 5 7.2 ESD Ratings............................................................... 5 7.3 Recommended Operating Conditions.........................5 7.4 Thermal Information....................................................6 7.5 Electrical Characteristics.............................................6 7.6 Typical Characteristics................................................ 9 8 Detailed Description...................................................... 11 8.1 Overview................................................................... 11 8.2 Functional Block Diagram......................................... 11 8.3 Feature Description...................................................12 8.4 Device Functional Modes..........................................18 9 Application and Implementation.................................. 22 9.1 Application Information............................................. 22 9.2 Typical Application.................................................... 25 9.3 System Examples..................................................... 33 10 Power Supply Recommendations..............................35 11 Layout........................................................................... 36 11.1 Layout Guidelines................................................... 36 11.2 Layout Example...................................................... 37 12 Device and Documentation Support..........................38 12.1 Device Support....................................................... 38 12.2 Receiving Notification of Documentation Updates..38 12.3 Support Resources................................................. 38 12.4 Trademarks............................................................. 38 12.5 Electrostatic Discharge Caution..............................38 12.6 Glossary..................................................................38 13 Mechanical, Packaging, and Orderable Information.................................................................... 39 4 Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Revision B (June 2020) to Revision C (October 2021) Page • Updated the numbering format for tables, figures, and cross-references throughout the document. ................1 • Added non-wettable flank options.......................................................................................................................1 • Added Section 5 ................................................................................................................................................ 3 Changes from Revision A (May 2018) to Revision B (June 2020) Page • Added functional safety bullet to Section 1 ........................................................................................................1 2 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 5 Device Comparison Table PART NUMBER LM51501QRUMRQ1 LM51501QRUMTQ1 LM51501QURUMRQ1 Copyright © 2021 Texas Instruments Incorporated PACKAGE OUTLINE WETTABLE (WF)/NON-WETTABLE FLANKS (NON-WF) RUM0016C WF RUM0016F Non-WF Submit Document Feedback 3 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 SYNC 1 STATUS 2 VSET RT COMP AP VIN 6 Pin Configuration and Functions 16 15 14 13 AP 12 CS 11 AGND EP PGND VOUT 4 9 LO 5 6 7 8 AP NC AP AVCC 10 NC 3 PVCC EN Figure 6-1. 16-Pin WQFN RUM Package (Top View) Table 6-1. Pin Functions PIN NO. I/O(1) DESCRIPTION 1 SYNC I External synchronization clock input pin. The internal oscillator is synchronized to an external clock by applying a pulse signal into the SYNC pin in the start-stop configuration. Connect directly to ground if not used or in an emergency call configuration. Maximum duty cycle limit can be programmed by controlling the external synchronization clock frequency. 2 STATUS O Status indicator with an open-drain output stage. An internal pulldown switch holds the pin low when the device is not boosting. The pin can be left floating if not used. 3 EN I Enable pin. If EN is below 1 V, the device is in shutdown mode. The pin must be raised above 2 V to enable the device. Connect directly to the VOUT pin for an automatic boost. 4 VOUT I/P Boost output voltage-sensing pin and input to the VCC regulator. Connect to the output of the boost converter. 5 PVCC O/P Output of the VCC bias regulator. Decouple locally to PGND using a low-ESR or low-ESL ceramic capacitor placed as close to the device as possible. 6 NC — No internal electrical connection. Leave the pin floating or connect directly to ground. 7 AVCC I/P Analog VCC supply input. Decouple locally to AGND using a 0.1-µF, low-ESR or low-ESL ceramic capacitor placed as close to the device as possible. Connect to the PVCC pin through 10-Ω resistor. 8 NC — No internal electrical connection. Leave the pin floating or connect directly to ground. 9 LO O N-channel MOSFET gate drive output. Connect to the gate of the N-channel MOSFET through a short, low inductance path. 10 PGND G Power ground pin. Connect to the ground connection of the sense resistor through a wide and short path. 11 AGND G Analog ground pin. Connect to the analog ground plane through a wide and short path. 12 CS I Current sense input pin. Connect to the positive side of the current sense resistor through a short path. 13 COMP O Output of the internal transconductance error amplifier. The loop compensation components must be connected between this pin and AGND. 14 RT I Switching frequency setting pin. The switching frequency is programmed by a single resistor between RT and AGND. 15 VSET I Configuration selection and VOUT regulation target programming pin. During initial power on, a resistor between the VSET pin and AGND configures the VOUT regulation target and the configuration. 16 VIN I Boost input voltage sensing pin. Connect to the input supply of the boost converter. — EP — — (1) 4 NAME AP — Exposed pad of the package. No internal electrical connection to silicon die. The EP is electrically connected to anchor pads. The EP must be connected to the large ground copper plain to reduce thermal resistance. Anchor pad of the package. No internal electrical connection to silicon die. The AP is electrically connected to the EP. The AP can be left floating or soldered to the ground copper. G = Ground, I = Input, O = Output, P = Power Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 7 Specifications 7.1 Absolute Maximum Ratings Over the recommended operating junction temperature range of –40°C to 150°C (unless otherwise specified)(1) MIN MAX VIN to AGND –0.3 65 VOUT to AGND –0.3 65 EN to AGND –0.3 65 RT to Input Output AGND(2) –0.3 AVCC + 0.3 SYNC to AGND –0.3 7 VSET to AGND –0.3 7 CS to AGND (DC) –0.3 AVCC + 0.3 CS to AGND (40-ns transient) –1.0 AVCC + 0.3 CS to AGND (20-ns transient) –2.0 AVCC + 0.3 PGND to AGND –0.3 0.3 LO to AGND (DC) -0.3 PVCC + 0.3 LO to AGND (40-ns transient) –1.0 PVCC + 0.3 LO to AGND (20-ns transient) –2.0 PVCC + 0.3 STATUS to AGND(3) –0.3 65 COMP to AGND(2) V V –0.3 AVCC + 0.3 AVCC to AGND –0.3 7 PVCC to AVCC –0.3 0.3 TJ Junction temperature(4) –40 150 TSTG Storage temperature –55 150 (1) (2) (3) (4) UNIT ℃ 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 pin voltage is clamped by an internal circuit, and is not specified to have an external voltage applied. STATUS can go below ground during the STATUS low-to-high transition. The negative voltage on STATUS during this transition is clamped by an internal diode and it does not damage the device. High junction temperatures degrade operating lifetimes. Operating lifetime is de-rated for junction temperatures greater than 125°C. 7.2 ESD Ratings Human body model (HBM), per AEC V(ESD) (1) Electrostatic discharge Charged device model (CDM), per AEC Q100-011 Q100-002(1) MIN MAX –2000 2000 Corner pins –750 750 Other pins –500 500 UNIT V AEC Q100-002 indicates that HBM stressing shall be in accordance with the ANSI/ESDA/JEDEC JS-001 specification. 7.3 Recommended Operating Conditions Over the recommended operating junction temperature range of –40°C to 150°C (unless otherwise specified)(1) MIN VVIN Boost input voltage sense VVOUT Boost output voltage VEN EN input sense(2) voltage(3) VVCC PVCC VSYNC SYNC input VCS Current sense input FSW Typical switching frequency Copyright © 2021 Texas Instruments Incorporated NOM MAX UNIT 1.5 42 V 5 42 V 0 42 V 5.5 V 5.5 V 4.5 0 5 0 0.3 220 2300 V kHz Submit Document Feedback 5 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Over the recommended operating junction temperature range of –40°C to 150°C (unless otherwise specified)(1) MIN FSYNC TJ (1) (2) (3) (4) MAX UNIT Synchronization pulse frequency 220 2300 kHz temperature(4) –40 150 °C Operating junction NOM Operating Ratings are conditions under the device is intended to be functional. For specifications and test conditions, see the Electrical Characteristics. The device requires a minimum 5 V at the VOUT pin to start up. VPVCC should be less than VVOUT + 0.3. High junction temperatures degrade operating lifetimes. Operating lifetime is de-rated for junction temperatures greater than 125°C. 7.4 Thermal Information LM51501-Q1 THERMAL METRIC(1) UNIT RUM (WQFN) 16 PINS RθJA Junction-to-ambient thermal resistance 44.4 °C/W RθJC(top) Junction-to-case (top) thermal resistance 33.4 °C/W RθJB Junction-to-board thermal resistance 19.5 °C/W ψJT Junction-to-top characterization parameter 0.5 °C/W ψJB Junction-to-board characterization parameter 19.3 °C/W RθJC(bot) Junction-to-case (bottom) thermal resistance 2.0 °C/W (1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application report (SPRA953). 7.5 Electrical Characteristics Typical values correspond to TJ = 25°C. Minimum and maximum limits apply over TJ = –40°C to 125°C. Unless otherwise stated, VVOUT = 9.5 V, RT = 9.09 kΩ PARAMETER TEST CONDITIONS MIN TYP MAX UNIT 5 12 µA SUPPLY CURRENT ISHUTDOWN(VOUT) VOUT shutdown current VVOUT = 12 V, VEN = 0 V ISTANDBY(VOUT) VOUT standby current (PVCC in regulation, STATUS is low) VVOUT = 12 V, VEN = 3.3 V, RSET = 90.9 kΩ 15 25 µA IWAKEUP(VOUT) VOUT operating current (exclude the current into the RT resistor) VVOUT = 11.5 V, VEN = 2.5 V, nonswitching, RT = 9.09 kΩ 1.2 2.0 mA ISHUTDOWN(VIN) VIN shutdown current VVIN = 12 V, VEN = 0 V 0.1 0.5 µA ISTANDBY(VIN) VIN standby current VVIN = 12 V, VEN = 3.3 V, RSET = 29.4 kΩ 0.1 0.5 µA IWAKEUP(VIN) VIN operating current VVIN = 11.5 V, VEN = 2.5V, nonswitching, RT = 9.09 kΩ 30 45 µA PVCC regulation VVOUT = 6.0 V, no load, wake-up mode 4.75 5 5.25 V VCC REGULATOR VVCC-REG-NOLOAD VVCC-REG-FULLLOAD PVCC regulation VVOUT = 5.0 V, IPVCC = 70 mA 4.5 4.8 VVCC-UVLO-RISING AVCC UVLO threshold AVCC rising 4.1 4.3 4.5 V V VVCC-UVLO-FALLING AVCC UVLO threshold AVCC falling 3.9 4.1 4.3 V VVCC-UVLO-HYS AVCC UVLO hysteresis IVCC-CL PVCC sourcing current limit VPVCC = 0 V, wake-up mode VEN-RISING Enable threshold EN rising VEN-FALLING Enable threshold EN falling IEN EN bias current VEN = 42 V VOUT regulation target RSET = 29.4 kΩ or 90.9 kΩ 0.2 V 75 mA ENABLE 1.7 1 2 1.3 V V 100 nA 6.12 V 6.0V SETTING VVOUT-REG 6 Submit Document Feedback 5.88 6.00 Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Typical values correspond to TJ = 25°C. Minimum and maximum limits apply over TJ = –40°C to 125°C. Unless otherwise stated, VVOUT = 9.5 V, RT = 9.09 kΩ PARAMETER TEST CONDITIONS MIN TYP MAX UNIT VVOUT-WAKEUP VOUT wake-up threshold (VVOUT-REG + RSET = 29.4 kΩ or 90.9 kΩ, VOUT 3%) falling 6.06 6.18 6.30 V VVOUT-STANDBY1 VOUT standby threshold (VVOUT-REG + RSET = 90.9 kΩ, VOUT rising 6%, EC config) 6.23 6.36 6.49 V VVOUT-STATUS-OFF VOUT status off threshold (VVOUT-REG + 12%, EC config) RSET = 90.9 kΩ, VOUT rising 6.59 6.72 6.85 V VVOUT-STANDBY2 VOUT standby threshold (VVOUT-REG + RSET = 29.4 kΩ, VOUT rising 24%, SS config) 7.30 7.44 7.54 V VVIN-STANDBY VIN standby threshold (VVOUT-WAKEUP + 1.0 V, SS config) RSET = 29.4 kΩ, VIN rising 7.04 7.18 7.32 V VVOUT-REG VOUT regulation target RSET = 19.1 kΩ or 71.5 kΩ 6.37 6.50 6.63 V VVOUT-WAKEUP VOUT wake-up threshold (VVOUT-REG + RSET = 19.1 kΩ or 71.5 kΩ, VOUT 3%) falling 6.56 6.70 6.83 V VVOUT-STANDBY1 VOUT standby threshold (VVOUT-REG + RSET = 71.5 kΩ, VOUT rising 6%, EC config) 6.75 6.89 7.03 V VVOUT-STATUS-OFF VOUT status off threshold (VVOUT-REG + 12%, EC config) RSET = 71.5 kΩ, VOUT rising 7.13 7.28 7.43 V VVOUT-STANDBY2 VOUT standby threshold (VVOUT-REG + RSET = 19.1 kΩ, VOUT rising 24%, SS config) 7.92 8.06 8.16 V VVIN-STANDBY VIN standby threshold (VVOUT-WAKEUP + 1.0 V, SS config) RSET = 19.1 kΩ, VIN rising 7.54 7.70 7.85 V VVOUT-REG VOUT regulation target RSET = 9.53 kΩ or 54.9 kΩ 9.31 9.50 9.69 V VVOUT-WAKEUP VOUT wake-up threshold (VVOUT-REG + RSET = 9.53 kΩ or 54.9 kΩ, VOUT 3%) falling 9.59 9.79 9.98 V VVOUT-STANDBY1 VOUT standby threshold (VVOUT-REG + RSET = 54.9 kΩ, VOUT rising 6%, EC config) 9.87 10.07 10.27 V VVOUT-STATUS-OFF VOUT status off threshold (VVOUT-REG + 12%, EC config) RSET = 54.9 kΩ, VOUT rising 10.43 10.64 10.85 V VVOUT-STANDBY2 VOUT standby threshold (VVOUT-REG + RSET = 9.53 kΩ, VOUT rising 24%, SS config) 11.55 11.78 11.95 V VVIN-STANDBY VIN standby threshold (VVOUT-WAKEUP + 1.0 V, SS mode) RSET = 9.53 kΩ, VIN rising 10.57 10.79 11.00 V VVOUT-REG VOUT regulation target RSET = GND or 41.2 kΩ 11.27 11.50 11.73 V VVOUT-WAKEUP VOUT wake-up threshold (VVOUT-REG + RSET = GND or 41.2 kΩ, VOUT falling 3%) 11.61 11.85 12.08 V VVOUT-STANDBY1 VOUT standby threshold (VVOUT-REG + RSET = 41.2 kΩ, VOUT rising 6%, EC config) 11.95 12.19 12.43 V VVOUT-STATUS-OFF VOUT status off threshold (VVOUT-REG + 12%, EC config) 12.62 12.88 13.14 V VVOUT-STANDBY2 VOUT standby threshold (VVOUT-REG + RSET = GND, VOUT rising 24%, SS config) 13.98 14.26 14.55 V VVIN-STANDBY VIN standby threshold (VVOUT-WAKEUP + 1.0 V, SS config) 12.52 12.85 13.10 V 6.5V SETTING 9.5V SETTING 11.5V SETTING RSET = 41.2 kΩ, VOUT rising RSET = GND, VIN rising RT VRT-REG RT regulation voltage 1.2 V CLOCK SYNCHRONIZATION VSYNC-RISING SYNC rising threshold VSYNC-FALLING SYNC falling threshold Copyright © 2021 Texas Instruments Incorporated 2.0 0.4 1.5 2.4 V V Submit Document Feedback 7 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Typical values correspond to TJ = 25°C. Minimum and maximum limits apply over TJ = –40°C to 125°C. Unless otherwise stated, VVOUT = 9.5 V, RT = 9.09 kΩ PARAMETER TEST CONDITIONS MIN TYP MAX UNIT PULSE WIDTH MODULATION AND OSCILLATOR FSW1 Switching frequency RT = 93.1 kΩ 204 239 270 kHz FSW2 Switching frequency RT = 9.09 kΩ 2100 2300 2500 kHz FSW3 Switching frequency RT = 9.09 kΩ, FSYNC = 2.0 MHz TON-MIN Forced minimum on time SS config, VCOMP = 0 V DMIN Minimum duty cycle limit (EC config) DMAX 2000 30 50 kHz 70 ns RT = 9.09 kΩ, VVIN = 1.5 V, VVOUT = 6.5 V, VCOMP = 0 V 59 % RT = 93.1 kΩ, VVIN = 7.6 V, VVOUT = 9.5 V, VCOMP = 0 V 16 % SS config, RT = 9.09 kΩ 83 87 91 % EC config, RT = 93.1 kΩ 83 87 93 % VVIN = 7.13 V, VVOUT = 9.5 V at 25% DC 102 120 138 mV VVIN = 4.75 V, VVOUT = 9.5 V at 50% DC 102 120 138 mV VVIN = 2.38 V, VVOUT = 9.5 V at 75% DC 102 120 138 mV COMP souring current VCOMP = 0 V 312 COMP sinking current VCOMP = 1.5 V 120 Maximum duty cycle limit CURRENT SENSE VCLTH Current Limit threshold (CS-AGND)(1) ERROR AMPLIFIER Gm Transconductance 2 COMP clamp voltage 2.4 COMP to PWM offset mA/V µA µA 2.6 V 0.3 V STATUS Low-state voltage drop 1-mA sinking STATUS rise to LO delay 5-kΩ pullup to 5 V 0.1 High-state voltage drop 50-mA sinking 0.075 V Low-state voltage drop 50mA sourcing 0.055 V 175 °C 15 °C 4 5 V 6 µs MOSFET DRIVER THERMAL SHUTDOWN (TSD) Thermal shutdown threshold Thermal shutdown hysteresis (1) 8 Temperature rising VCL at the current limit comparator input is 10 × VCLTH Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 7.6 Typical Characteristics 126 20 Current Limit Threshold at CS (mV) Peak Current in Current Limit (A) 19.5 19 18.5 18 17.5 17 16.5 16 15.5 6.0V output 6.5V output 9.5V output 11.5V output 15 14.5 14 2 3 4 5 6 7 Supply Voltage (V) 8 9 6.0V output 6.5V output 9.5V output 11.5V output 124 122 120 118 116 114 20 10 30 40 D001 Figure 7-1. Peak Inductor Current vs Supply Voltage (FSW = 440 kHz, RS = 7 mΩ, RF = 100 Ω, CF = 2.2 nF) 50 60 Duty Cycle (%) 70 80 D002 Figure 7-2. Current Limit Threshold at CS vs Duty Cycle 6 6 5.5 5 5 4.5 4 VPVCC (V) VPVCC (V) 4 3 3.5 3 2.5 2 2 1.5 1 1 0.5 0 0 0 20 40 60 80 IPVCC (mA) 100 120 90 Duty Cycle Limit in EC Config (%) 100 2500 2250 2000 1750 1500 1250 1000 750 500 250 0 10 20 30 40 50 60 RT (k:) 70 80 Figure 7-5. Frequency vs RT Copyright © 2021 Texas Instruments Incorporated 1 1.5 2 90 2.5 3 3.5 VVOUT (V) 4 4.5 5 5.5 6 D004 Figure 7-4. VPVCC vs VVOUT (EN = 3.3 V, IPVCC = 10 mA, VOUT Rising) 2750 0 0.5 D003 Figure 7-3. VPVCC vs IPVCC (VOUT = 6 V) Frequency (kHz) 0 140 100 D005 VVOUT=6.0V VVOUT=6.5V VVOUT=9.5V VVOUT=11.5V 80 70 60 50 40 30 20 10 0 0 1 2 3 4 5 6 7 VVIN (V) 8 9 10 11 12 Dmin Figure 7-6. Duty Cycle Limit in EC Configuration vs VVIN Submit Document Feedback 9 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 20 100 18 95 16 Efficiency (%) IVOUT (uA) 14 Shutdown Standby 12 10 8 6 4 90 85 80 VSUPPLY=7.5V VSUPPLY=6.5V VSUPPLY=5.5V VSUPPLY=4.5V VSUPPLY=3.5V 75 2 0 -60 70 -40 -20 0 20 40 60 80 Temperature (°C) 100 120 140 160 Figure 7-7. IVOUT vs Temperature 10 Submit Document Feedback D007 0 0.3 0.6 0.9 1.2 1.5 Load Current (A) 1.8 2.1 2.4 D008 Figure 7-8. Efficiency vs Load Current (VLOAD = 9.5 V, FSW = 440 kHz, SS Configuration) Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 8 Detailed Description 8.1 Overview The LM51501-Q1 device is a wide input range automotive boost controller designed for automotive start-stop or emergency-call applications. The device can maintain the output voltage from a vehicle battery during automotive cranking or from a backup battery during the loss of vehicle battery. The wide input range of the device covers automotive load dump transient. The control method is based upon peak current mode control. To extend the battery life time, the LM51501-Q1 features a low IQ standby mode with automatic wake-up and standby control. The device stays in low IQ standby mode when the boost operation is not required, and automatically enters the wake-up mode when the output voltage drops below the preset wake-up threshold. High value feedback resistors are included inside the device to minimize leakage current in low IQ standby mode. The LM51501-Q1 operates in one of two selectable configurations when waking up. In Start-Stop configuration (SS configuration), the device runs at a fixed switching frequency without any pulse skipping until entering into the standby mode, which helps to have a fixed EMI spectrum. In Emergency-Call configuration (EC configuration), the device will skip pulses as it automatically alternates between low IQ standby mode and wake-up mode to extend the battery life in light load conditions. The LM51501-Q1 switching frequency is programmable from 220 kHz to 2.3 MHz. Fast switching (≥ 2.2 MHz) minimizes AM band interference and allows for a small solution size and fast transient response. A single resistor at the VSET pin programs the target output regulation voltage as well as the configuration. This eliminates the need for an external feedback resistor divider which enables low IQ operation. The device also features clock synchronization in the SS configuration, low quiescent current in shutdown mode, a boost status indicator, adjustable cycle-by-cycle current will limit, and thermal shutdown protection. 8.2 Functional Block Diagram VSUPPLY D1 VLOAD LM COUT CIN RLOAD STATUS VIN (SS Mode) VIN_STANDBY StatusB VSET Standby RSET S Q R Q S ± REF + Wakeup FB VOUT ± VO_WAKE REF VOUT + (EC Mode) VO_STATUS_OFF StatusB + VIN_STANDBY (SS Mode) 2.0 V/1.0 V Ready CAVCC PVCC LM51501 VCC_OK VCC Regulator Enable Standby TSD VCL + 0.3 V AVCC REF + VOUT Enable ± VOUT ± R Q EN VOUT-STANDBY ± VO_STANDBY VSET Ready POWER ON VOLTAGE SELECT Q + ± VCC_OK C/L + S Q R Q RAVCC CPVCC VCC UVLO LO VCS_OFFSET Wakeup + ISLOPE ± ± VCS VCS_OFFSET + PGND AGND 30 uA peak DMAX/Forced_Toff CLOCK GENERATOR GM AMP Q1 DMIN/Forced_Ton C/L + COMP RCOMP RT SYNC ± FB REF PWM + A = 10 ± CS RSL (optional) RF 2k TLEB CF RS 0.3 V RT CCOMP Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 11 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 8.3 Feature Description 8.3.1 Enable (EN Pin) When the EN pin voltage is less than 1 V, the LM51501-Q1 is in shutdown mode with all other functions disabled. To turn on the internal VCC regulator and begin the start-up sequence, the EN pin voltage must be greater than 2 V. If the EN pin is controlled by user input, TI recommends supplying a voltage greater than 3 V at the EN pin. If the EN pin is not controlled by user input, connect the EN pin to the VOUT pin directly. See Section 8.4 for more detailed information. 8.3.2 High Voltage VCC Regulator (PVCC, AVCC Pin) The LM51501-Q1 contains an internal high voltage VCC regulator. The VCC regulator turns on when the EN pin voltage is greater than 2 V. The VCC regulator is sourced from the VOUT pin and provides 5 V (typical) bias supply for the N-channel MOSFET driver and other internal circuits. The VCC regulator sources current into the capacitor connected to the PVCC pin with a minimum of 75-mA capability when the LM51501-Q1 is in wake-up mode during the device configuration period. The maximum sourcing capability is decreased to 17 mA in standby mode. The recommended PVCC capacitor is 4.7 µF to 10 µF. In normal operation, the PVCC pin voltage is either 5 V or VVOUT + 0.3 V, whichever is lower. The AVCC pin is the analog bias supply input of the LM51501-Q1. The recommended AVCC capacitor is 0.1 μF. Connect to the PVCC pin through a 10-Ω resistor. 8.3.3 Power-On Voltage Selection (VSET Pin) During initial power on, the VOUT regulation target and the configuration are configured by a resistor connected between the VSET and the AGND pins. The configuration starts when the EN pin voltage is greater than 2 V and the AVCC voltage crosses the AVCC UVLO threshold, which typically requires 50 µs to finish. To reset and reconfigure, the EN should be toggled below 1 V or the AVCC/VOUT must be fully discharged. EN Wake-up or standby Configuration AVCC Shutdown Configuration Shutdown Wake-up or standby VCC UVLO 50 us 50 us Figure 8-1. Power-On Voltage Selection The VOUT regulation target can be programmed to 6.0 V, 6.5 V, 9.5 V, or 11.5 V with the appropriate resistor with 5% tolerance. The configuration can be selected as either SS or EC configuration. The LM51501-Q1 will not switch during the 50-µs configuration time. Table 8-1. VSET Resistors(1) CONFIGURATION (1) 12 EMERGENCY-CALL START-STOP VOUT regulation target 6.0 V 6.5 V 9.5 V 11.5 V 6.0 V 6.5 V 9.5 V 11.5 V RSET [Ω] 90.9k 71.5k 54.9k 41.2k 29.4k 19.1k 9.53k Ground If other output regulation targets are required, contact the sales office or distributors for availability. Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 8.3.4 Switching Frequency (RT Pin) The switching frequency of the LM51501-Q1 is set by a single RT resistor connected between the RT and the AGND pins. The resistor value to set the switching frequency (FSW) is calculated using Equation 1. RT 2.233 u 1010 FSW _ RT 619 : TYPICAL (1) The RT pin is regulated to 1.2 V by the internal RT regulator during wake-up. 8.3.5 Clock Synchronization (SYNC Pin in SS Configuration) In SS configuration, the switching frequency of the LM51501-Q1 can be synchronized to an external clock by directly applying a pulse signal to the SYNC pin. The internal clock of the LM51501-Q1 is synchronized at the rising edge of the external clock. The device ignores the rising edge input during forced off-time. The external synchronization pulse must be greater than the 2.4 V in the high logic state and must be less than 0.4 V in the low logic state. The duty cycle of the external synchronization pulse is not limited, but the minimum pulse width should be greater than 100 ns. Because the maximum duty cycle limit and the peak current limit threshold are affected by synchronizing the switching frequency to an external synchronization pulse, take extra care when using the clock synchronization function. See Section 8.3.11 and Section 8.3.7 for more detailed information. If the minimum input supply voltage of the boost converter is greater than ¼ of the VOUT regulation target (VVOUT-REG), the frequency of the external synchronization pulse (FSYNC) should be within +15% and –15% of the typical free-running switching frequency (FSW(TYPICAL)) as shown in Equation 2: 0.85 ´ FSW_RT(TYPICAL) £ FSYNC £ 1.15 ´ FSW_RT(TYPICAL) (2) In this range, a maximum 1:4 (VSUPPLY:VLOAD) step-up ratio is allowed. A higher step-up ratio can be achieved by supplying a lower frequency synchronization pulse. 1:5 step-up ratio can be achieved by selecting FSYNC within –25% and –15% of the FSW_RT(TYPICAL). 0.75 ´ FSW_RT(TYPICAL) £ FSYNC £ 0.85 ´ FSW_RT(TYPICAL) (3) In this range, a maximum 1:5 (VSUPPLY:VLOAD) step-up ratio is allowed. 8.3.6 Current Sense, Slope Compensation, and PWM (CS Pin) The LM51501-Q1 features low-side current sense amplifier with a gain of 10, and provides an internal slope compensation ramp to prevent subharmonic oscillation at high duty cycle. The device generates the slope compensation ramp using a sawtooth current source with a slope of 30 µA × FSW (typical). This current flows through an internal 2-kΩ resistor and out of the CS pin. The slope compensation ramp is determined by the RT resistor and is 60 mV × FSW (typical) at the input of the current sense amplifier and 600 mV × FSW (typical) at the output of the current sense amplifier. The slope compensation ramp can be increased by adding an external slope resistor (RSL) between the sense resistor (RS) and the CS pin, but take extra care when using the RSL, because the peak current limit is affected by adding RSL. See tSection 8.3.7 for more detailed information. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 13 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Q1 Current Limit ± VCL +0.3 V 30 uA peak + ISLOPE PWM + + ± ± 2k CS RSL (optional) + A = 10 ± RF CF 0.3 V RS COMP Figure 8-2. Current Sensing and Slope Compensation According to peak current mode control theory, the slope of the compensation ramp must be greater than half of the sensed inductor current falling slope to prevent subharmonic oscillation at high duty cycle. Therefore, the minimum amount of slope compensation should satisfy the inequality in Equation 4. 0.5 ´ (VLOAD + VF ) - VSUPPLY × RS × Margin < 30mA ´ (2kΩ + RSL )× FSW LM (4) VF is a forward voltage drop of D1, the external diode. 1.2 is recommended as a margin to cover non-ideal factors. If required, RSL can be added to increase the slope of the compensation ramp from half to 82% of the slope of the sensed inductor current during the falling slope. The typical RSL value is calculated using Equation 5. The maximum RSL value is 1 kΩ. 0.82 ´ (VLOAD + VF ) - VSUPPLY × RS = 30mA ´ (2kΩ + RSL )× FSW LM (5) The PWM comparator in Figure 8-2 compares the sum of the sensed inductor current, the slope compensation ramp, and a 0.3-V (typical) internal COMP-to-PWM offset with the COMP pin voltage (VCOMP), and will terminate the present cycle if the sum is greater than VCOMP. 8.3.7 Current Limit (CS Pin) The LM51501-Q1 features cycle-by-cycle peak current limit without subharmonic oscillation at high duty cycle. If the sum of the sensed inductor current and the slope compensation ramp exceeds the current limit threshold at the current limit comparator input (VCL), the current limit comparator immediately terminates the present cycle. To minimize the peak current limit variation due to changes in either the supply voltage or the output voltage, the device features a variable current limit threshold which is calculated using Equation 6. VCL = 1.2 + 0.6 × (VVOUT - VVIN ) [V] VVOUT-REG (6) The cycle-by-cycle peak inductor current limit (IPEAK-CL) in steady-state is calculated using Equation 7 and Equation 8: VCL - 10 ´ 30mA ´ (2kW + RSL ) ´ IPEAK -CL = 14 Submit Document Feedback 10 ´ RS FSW_RT FSYNC ´D (7) Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com D = 1- SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 VSUPPLY VLOAD +VF (8) FSYNC is included in the equation because the peak amplitude of the slope compensation varies with the frequency of the external synchronization clock. Substitute FSW_RT for FSYNC if clock synchronization is not used. Boost converters have a natural pass-through path from the supply to the load through the high-side power diode (D1). Due to this path, boost converters cannot provide current limit protection when the output voltage is close to or less than the input supply voltage. A small external RC filter (RF, CF) at the CS pin is required to overcome the leading edge spike of the current sense signal. Select an RF value that is greater than 30 Ω and a CF value that is greater than 1 nF. Due to the effect of the filter, the peak current limit is not valid when the on-time is less than 2 × RF × CF. 8.3.8 Feedback and Error Amplifier (COMP Pin) The LM51501-Q1 includes internal feedback resistors which are set based on the VSET pin resistor selection. These feedback resistors are disconnected from the VOUT pin in the standby mode to minimize quiescent current. The feedback resistor divider is connected to an internal transconductance error amplifier that features high output resistance (RO = 10 MΩ) and wide bandwidth (BW = 3 MHz). The internal transconductance error amplifier sources current which is proportional to the difference between the feedback resistor divider voltage and the internal reference. The output of the error amplifier is connected to the COMP pin, allowing the use of a Type-2 loop compensation network. The RCOMP, CCOMP, and the optional CHF loop compensation components configure the error amplifier gain and phase characteristics to achieve a stable loop response. This compensation network creates a pole at very low frequency (FDP), a mid-band zero pole (FZ_EA), and a high-frequency pole (FP_EA). See Section 9.2.2.8 for more information. 8.3.9 Automatic Wake-Up and Standby The LM51501-Q1 wakes up when VVOUT drops below the VOUT wake-up threshold. The device goes into standby when VVOUT rises above the VOUT standby threshold in EC or SS configuration or when VVIN rises above the VIN standby threshold in SS configuration. The VOUT wake-up threshold is typically 3% higher than the VOUT regulation target. The STATUS output is released in 3 µs (with 50-kΩ pullup resistor to 5 V) after the wake-up event. The LO driver is enabled 6 µs after the STATUS output starts rising. VOUT VIN WAKEUP + + VVOUT-STANDBY REF VIN_STANDBY (SS Config) Standby Wakeup FB Q S Q R VO_STANDBY VOUT VO_WAKE + REF Figure 8-3. Automatic Wake-Up and Standby Control Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 15 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 In SS configuration, the VOUT standby threshold is typically 24% higher than the VOUT regulation target. The VIN standby threshold is typically 1 V higher than the VOUT wake-up threshold in SS configuration. To prevent chatter, the forward voltage drop of diode D1 must be less than 0.95 V. See Figure 8-7. VSUPPLY (Fast fall) Engine Cranking VLOAD VVOUT-STANDBY2 = 1.24 x VVOUT-REG VVIN-STANDBY = VVOUT-WAKE +1.0 when FSW is low VVOUT-WAKEUP = 1.03 x VVOUT-REG VVOUT-REG Wake-up/Standby Wake-up Standby Wake-up Standby STATUS Full load ILOAD Very light load Full load Figure 8-4. Automatic Wake-Up and Standby Operation in the SS Configuration (With Fast VSUPPLY Fall and Slow Switching) VSUPPLY (Slow fall) Engine Cranking VLOAD VVOUT-STANDBY2 = 1.24 x VVOUT-REG VVIN-STANDBY = VVOUT-WAKE +1.0 when FSW is fast VVOUT-WAKEUP = 1.03 x VVOUT-REG VVOUT-REG Wake-up Standby Standby W-up Wake-up/Standby Standby Wake-up Standby STATUS ILOAD Full load Very light load /No load Full load Figure 8-5. Automatic Wake-Up and Standby Operation in the SS Configuration (With Slow VSUPPLY Fall and Fast Switching) In EC configuration, the VOUT standby threshold is typically 6% higher than the VOUT regulation target. Because of the minimum duty cycle limit (see Section 8.4.3.2 section), the LM51501-Q1 alternates between the wake-up and the low IQ standby modes at medium or light load. See Figure 8-8. 16 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Vehicle Battery Disconnect VLOAD Vehicle Battery Reconnect VVOUT_STATUS_OFF = 1.12 x VVOUT-REG VVOUT-STANDBY1 = 1.06 x VVOUT-REG VVOUT-WAKEUP = 1.03 x VVOUT-REG VSUPPLY VVOUT-REG Wake-up W-up Standby Standby Standby Wake-up Standby STATUS ILOAD Full load Mid / Light load Full load Figure 8-6. Automatic Wake-Up and Standby Operation in EC Configuration To minimize output undershoot when waking up, the LM51501-Q1 boosts the VOUT regulation target during the first 128 cycles after the wake-up event. The regulation target becomes 3% higher than the original regulation target for 64 cycles, 2% higher for the next 32 cycles, and 1% higher for the final 32 cycles. The VOUT pin voltage can rise up above the VOUT standby threshold, even if switching stops at the VOUT standby threshold, because the energy stored in the inductor transfers to the output capacitor when switching stops. See Section 8.4 for more information about the automatic wake-up and standby operation. 8.3.10 Boost Status Indicator (STATUS Pin) STATUS is an open-drain output and requires a pullup resistor between 5 kΩ and 100 kΩ. The pin is pulled up after VVOUT falls below the VOUT wake-up threshold, and is toggled to a low logic state when VVIN rises above the VIN standby threshold in SS configuration or when VVOUT rises above the VOUT status off-threshold in EC configuration. The pin is also pulled to ground when EN < 1 V and VOUT is greater than about 2 V, when AVCC < VVCC-UVLO-FALLING or during thermal shutdown. 8.3.11 Maximum Duty Cycle Limit and Minimum Input Supply Voltage When designing a boost converter, the maximum duty cycle should be reviewed at the minimum supply voltage. The minimum input supply voltage which can achieve the target output voltage is estimated from Equation 9. VSUPPLY(MIN) » (VVOUT -REG + VF ) ´ (1 - DMAX ) ´ FSYNC + ISUPPLY(MAX) ´ RDCR + ISUPPLY(MAX) ´ (RDS(ON) + RS ) ´ DMAX FSW_RT (9) where • • • ISUPPLY(MAX) is the maximum input current. RDCR is the DC resistance of the inductor. and RDS(ON) is the on-resistance of the MOSFET. Substitute FSW_RT for FSYNC if clock synchronization is not used. The minimum input supply voltage can be decreased by supplying FSYNC because it is less than FSW_RT. This maximum duty cycle limit (DMAX) is 87% (typical), but may fall down below 80% if the external synchronization clock frequency is higher than 0.85 × FSW (TYPICAL). Select an FSYNC that is within –25% and –15% of the FSW (TYPICAL) if 1:5 step-up ratio is required for clock synchronization. The minimum input supply voltage can be further decreased by supplying a lower frequency external synchronization clock. See Section 8.3.5 for more information. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 17 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 8.3.12 MOSFET Driver (LO Pin) The LM51501-Q1 provides an N-channel MOSFET driver that can source or sink a peak current of 1.5 A. The driver is powered by the 5-V VCC regulator and is enabled when the EN pin voltage is greater than 2 V and the AVCC pin voltage is greater than the AVCC UVLO threshold. 8.3.13 Thermal Shutdown Internal thermal shutdown is provided to protect the LM51501-Q1 if the junction temperature exceeds 175°C (typical). When thermal shutdown is activated, the device is forced into a low power thermal shutdown state with the MOSFET driver and the VCC regulator is disabled. After the junction temperature is reduced (typical hysteresis is 15⁰C), the device is re-enabled. 8.4 Device Functional Modes 8.4.1 Shutdown Mode If the EN pin voltage is below 1 V, the LM51501-Q1 is in shutdown mode with all functions disabled except the EN. In shutdown mode, the device reduces the VOUT pin current consumption to below 5 µA (typical) and the STATUS pin is pulled to ground. The device can be enabled by raising the EN pin above 2 V and operates in either standby mode or the wake-up mode if VAVCC is greater than the AVCC UVLO threshold. Table 8-2. State of Each Pin in Shutdown Mode STATUS SYNC RT COMP EN VOUT PVCC/AVCC LO CS VIN VSET Grounded Disabled Disabled Disabled Enabled IQ ≤ 5 µA Disabled Grounded Disabled IQ ≈ 0.1 µA Disabled 8.4.2 Standby Mode If VOUT is greater than the VOUT standby threshold or the VIN is greater than the VIN standby threshold in the SS mode, the LM51501-Q1 enters into standby mode. In standby mode, most functions are disabled, including the thermal shutdown, to minimize the current consumption. The VOUT wake-up monitor is enabled in standby mode to allow wake-up if the VOUT voltage drops below the VOUT wake-up threshold. The VCC regulator reduces the sourcing capability to 17 mA in standby mode and the AVCC UVLO comparator is disabled. The VOUT standby threshold fulfills effectively the overvoltage protection (OVP) function. Table 8-3. State of Each Pin in Standby Mode STATUS Released or Grounded SYNC Disabled RT Disabled COMP Disabled EN VOUT PVCC/AVCC LO CS VIN VSET Enabled IQ ≤ 15 µA. VOUT wake-up monitor enabled Enabled IPVCC capability ≈ 17 mA Grounded Disabled IQ ≈ 0.1 µA Disabled 8.4.3 Wake-Up Mode The LM51501-Q1 wakes up from standby mode if VOUT drops below the VOUT wake-up threshold. There are two configurations when the device wakes up. One is start-stop configuration (SS configuration) and the other is emergency-call configuration (EC configuration). The configuration is selectable by the VSET resistor (see Table 8-1). 18 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 8.4.3.1 Start-Stop Configuration (SS Configuration) Bypass path D1 VSUPPLY VLOAD LM + ± Reverse Battery Protection Diode COUT Q1 RLOAD CIN Vehicle Battery RS VIN LO AGND CS STATUS SYNC LM51501 EN COMP VOUT RT RCOMP PGND VSET PVCC AVCC C VOUT CCOMP RT RSET Figure 8-7. Typical Start-Stop Application The LM51501-Q1 runs at fixed switching frequency without any pulse skipping in SS configuration. The device turns on the LO driver every cycle with TON-MIN until it enters standby mode, which helps to prevent EMI spectrum shifts. Because the MOSFET turns on every cycle, the boost converter output may be above the regulation target if the required on-time is less than the TON-MIN when the boost supply voltage is close to the VOUT regulation target or the load current is very small. The output voltage will rise above the VOUT regulation target if the one of the inequalities listed in Equation 10 or Equation 11 is true. D´ 1 FSW < TON-MIN (VSUPPLY ´ TON-MIN )2 FSW ´ > ILOAD 2 ´ LM (VLOAD + VF - VSUPPLY ) (10) (11) In SS configuration, the LM51501-Q1 enters into the standby mode if VOUT is greater than the VOUT standby threshold—which is 24% higher than the VOUT regulation target—or if VIN is greater than the VIN standby threshold. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 19 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 8.4.3.2 Emergency-Call Configuration (EC Configuration) Other loads + ± Vehicle Battery D1 VSUPPLY VLOAD LM + COUT Q1 CIN RLOAD Back-up battery RS VIN LO CS AGND STATUS SYNC LM51501 EN COMP RT RCOMP CCOMP RT PGND VOUT VSET PVCC AVCC CVOUT RSET Figure 8-8. Typical Emergency Call Application The EC configuration achieves high efficiency at light or medium load by alternating between the wake-up and the low IQ standby modes. In EC configuration, the LM51501-Q1 limits the minimum duty cycle programmed by VVOUT and VVIN. The minimum duty cycle limit is calculated using Equation 12. æ ö VVIN DMIN = 0.75 ´ ç 1 ÷ VVOUT -REG ø è (12) Due to this minimum duty cycle limit, the boost converter sources more current than required when the load current is relatively small. As a result, the output voltage increases and eventually crosses the VOUT standby threshold which is typically 6% higher than the VOUT regulation target. The LM51501-Q1 then goes into the low IQ standby mode. The LM51501-Q1 wakes up when VOUT drops below the VOUT wake-up threshold which is typically 3% higher than the VOUT regulation target. The device alternates between these two modes when the inequality in Equation 13 is true. 2 æ DMIN ö ç VSUPPLY ´ ÷ FSW ø FSW è ´ > ILOAD 2 ´ LM (VLOAD + VF - VSUPPLY ) (13) Assuming VLOAD = VVOUT = VVOUT-REG and VSUPPLY = VVIN, the skip cycle operation starts when the inequality in Equation 14 is true. 2 æ æ VLOAD - VSUPPLY ö ö çç VSUPPLY ´ 0.75 ´ ç ÷ ÷÷ VLOAD è øø è >ILOAD 2 ´ LM ´ FSW ´ (VLOAD + VF - VSUPPLY ) 20 Submit Document Feedback (14) Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 In EC configuration, the LM51501-Q1 does not generate any pulse if VCOMP is less than the 0.3 V and the required minimum duty cycle limit is zero. If the peak current limit is triggered before reaching the minimum duty cycle, the device terminates the LO driver output immediately. If VOUT is greater than the VOUT status-off threshold (typically 12% higher than the VOUT regulation target), the LM51501-Q1 pulls the STATUS pin low. In EC configuration, light-load efficiency is proportional with the inductor current ripple ratio. Table 8-4. State of Each Pin in Wake-Up Mode STATUS SYNC Enabled in SS Released configuratio n RT Enabled COMP Enabled EN Enabled VOUT PVCC/AVCC LO VOUT standby monitor is enabled. VOUT status-off Enabled IPVCC monitor is capability ≈ 75 mA enabled in EC configuration. PWM CS VIN VSET Enabled IQ ≈ 30 µA. VIN status-off monitor is enabled in SS configuration Disabled Table 8-5. Start-Stop vs Emergency-Call Configuration CONFIGURATION START-STOP VOUT regulation options EMERGENCY-CALL 6.0 V, 6.5 V, 9.5 V, 11.5 V VSET resistor value [Ω] 29.4k, 19.1k, 9.53k, GND 90.9k, 71.5k, 54.9k, 41.2k Clock Synchronization Yes No, SYNC should be grounded VOUT wake-up threshold [V] VOUT standby threshold [V] VVOUT-REG × 1.03 VVOUT-REG × 1.24 VVOUT-REG × 1.06 VOUT status-off threshold [V] N/A VVOUT-REG × 1.12 VIN standby threshold [V] VVOUT-REG × 1.03 + 1.0 V N/A STATUS pin control (Open-drain with pullup resistor) Released by VOUT wake-up Pulled down by VIN standby Released by VOUT wake-up Pulled down by VOUT status-off At heavy load when VVIN « VVOUT Pulse width modulation (PWM) At light or no load when VVIN « VVOUT LO turns on at every cycle in wake-up configuration. Skip cycle operation by alternating between wake-up and standby configurations. When VVIN ≈ VVOUT or VVIN ≥ VVOUT Maximum duty-cycle limit Copyright © 2021 Texas Instruments Incorporated Minimum on-time is limited Minimum duty cycle is limited LO turns on at every cycle in wake-up configuration. On-time is limited by TONMIN. VOUT goes out of regulation. Duty cycle can drop to 0%. No pulses if VCOMP < 0.3 V and DMIN ≤ 0%. Typically 87% Submit Document Feedback 21 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9 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, as well as validating and testing their design implementation to confirm system functionality. 9.1 Application Information The LM51501-Q1 is a non-synchronous boost controller. The following design procedure can be used to select the external components for the LM51501-Q1. Alternately, the WEBENCH® software can be used to generate complete designs. The WEBENCH software uses an iterative design procedure and accesses comprehensive data bases of components when generating a design. This section presents a simplified discussion of the design process. 9.1.1 Bypass Switch / Disconnection Switch Control The STATUS pin can be used to control an external bypass switch, which turns on when the boost is in standby mode, or to control an external disconnection switch that turns off when the boost is in standby mode. In Figure 9-1, a P-channel MOSFET is used to connect the boost supply input to the load directly when the boost is in standby mode. This bypass switch can be turned on slowly, but it must be turned off fast after the STATUS pin is pulled up by the wake-up event. The STATUS pin is rated to the absolute maximum 65 V. VSUPPLY VLOAD STATUS Figure 9-1. Bypass Switch Control Example In Figure 9-2, a P-channel MOSFET is used to disconnect the boost supply output from the battery when boost is not required. This disconnection switch can be turned off slowly, but it must be turned on fast after the STATUS pin is pulled up by the wake-up event. 22 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 VLOAD VBAT PVCC STATUS LM51501 Figure 9-2. Disconnection Switch Control Example 9.1.2 Loop Response The open-loop transfer function of a boost regulator is defined as the product of modulator transfer function and feedback transfer function. The modulator transfer function of a current mode boost regulator including a power stage with an embedded current loop can be simplified as a one load pole (FLP), one ESR zero (FZ_ESR), and one Right Half Plane (RHP) zero (FRHP) system, which can be explained as follows. Modulator transfer function is defined as Equation 15: æ ö æ ö s s ç1 + ÷ ´ ç1 ÷ ç ÷ 2p ´ FZ_ESR ø è 2p ´ FRHP ø Vˆ LOAD (s) è = AM ´ æ ö Vˆ COMP (s) s ç1 + ÷ 2p ´ FLP ø è (15) where RLOAD D' ´ R 2 S ´ 10 • 2 FLP = [Hz] 2 p ´ R LOAD ´ COUT • 1 FZESR = [Hz] 2 p ´ R ESR ´ COUT • R ´ (D ')2 FRHP = LOAD [Hz] 2p ´ LM • AM = RESR is the equivalent series resistance (ESR) of the output capacitor which is specified in the capacitor data sheet. RCOMP, CCOMP, and CHF (see Figure 9-3) configure the error amplifier gain and phase characteristics to produce a stable voltage loop with fast response. This compensation network creates a dominant pole at low frequency (FDP_EA), a mid-band zero pole (FZ_EA), and a high frequency pole (FP_EA). Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 23 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 The feedback transfer function is defined as Equation 16: æ ö s ç1 + ÷ ç ˆ 2p ´ FZ_EA ÷ø VCOMP(S) è = AFB ´ æ ö æ Vˆ LOAD(S) s s ç1 + ÷ ´ ç1 + ç ÷ ç 2 F 2 F p ´ p ´ DP_EA ø è P_EA è ö ÷ ÷ ø (16) where • • • • 1.2 ´ RO ´ Gm VLOAD 1 FDP_EA = [Hz] 2p ´ RO ´ CCOMP 1 FZ_EA = [Hz] 2p ´ RCOMP ´ CCOMP 1 1 » FP_EA = [Hz] æ CCOMP ´ CHF ö 2p ´ RCOMP ´ CHF 2p ´ RCOMP ´ ç ÷ è CCOMP + CHF ø AFB = RO (≈ 10 MΩ) is the output resistance of the error amplifier and Gm (≈ 2 mA/V) is the transconductance of the error amplifier. Assuming FLP is canceled by FZ_EA, FRHP is much higher than crossover frequency (FCROSS), and if FZ_ESR is either canceled by FP_EA or FZ_ESR, then that is much higher than FCROSS. The open-loop transfer function can be simplified as Equation 17: T(s) = AM ´ AFB ´ 1 æ s ç1 + ç 2 F p ´ DP_EA è ö ÷ ÷ ø (17) Because |T(s)|=1 at the crossover frequency, the crossover frequency can be simply estimated using those assumptions. FCROSS » 24 [AM ´ AFB ]2 - 1 2p ´ RO ´ CCOMP Submit Document Feedback [Hz] (18) Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9.2 Typical Application The LM51501 requires a minimum number of external components to work. Figure 9-3 includes all optional components as an example. CSNB RSNB VSUPPLY VLOAD D1 LM Q1 ILOAD COUT CIN RLOAD RF RG CVIN RVOUT RSL RS CF (leave floating if not used) LO VIN CS CVOUT AGND & PGND VOUT STATUS SYNC (connect to GND if not used) (connect to VOUT if not used) EN LM51501 COMP RT VSET PVCC AVCC RCOMP RAVCC RT CCOMP RSET CPVCC CHF CAVCC Optional components are in blue Figure 9-3. Typical Circuit With Optional Components 9.2.1 Design Requirements Table 9-1 lists the design parameters for Figure 9-3. Table 9-1. Design Example Parameters DESIGN PARAMETER VALUE Target Application Start-stop Minimum Input Supply Voltage (VSUPPLY(MIN)) 2.5 V Target Output Voltage (VLOAD) 9.5 V Maximum Load Current (ILOAD) 2.6 A (≈ 25 Watt) Switching Frequency (FSW) 440 kHz D1 Diode Forward Voltage Drop 0.7 V Maximum Inductor Current Ripple Ratio (RR) 0.6 (= 60%) Estimated Full Load Efficiency (Eff) 0.8 (= 80%) Current Limit Margin (MCL) 1.2 (= 120%) FLP over FCROSS (K1) 0.18 (FLP = 0.18 × FCROSS) FZ_EA over FLP (K2) 3 (FZ_EA = 3 × FLP) 9.2.2 Detailed Design Procedure 9.2.2.1 Custom Design With WEBENCH® Tools Click here to create a custom design using the LM51501-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. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 25 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 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. 9.2.2.2 RSET Resistor Select the value of RSET. Referring to Table 8-1, 9.53 kΩ is chosen to target 9.5 V in SS configuration. In general, about 5% to approximately 10% output undershoot should be considered when selecting the VOUT regulation target. 9.2.2.3 RT Resistor The value of RT for 440-kHz switching frequency is calculated in Equation 19: RT 2.233 u 1010 FSW _ RT 2.233 u 1010 440 k 619 TYPICAL 619 50.1k: (19) A standard value of 49.9 kΩ is chosen for RT. In general, higher frequency boost converters are smaller and faster, but they also have higher switching losses and lower efficiency. 9.2.2.4 Inductor Selection (LM) When selecting the inductor, consider three key parameters: inductor current ripple ratio (RR), falling slope of the inductor current, and RHP zero frequency (FRHP). Inductor current ripple ratio is selected to have a balance between core loss and copper loss. The falling slope of the inductor current must be low enough to prevent subharmonic oscillation at high duty cycle (additional RSL resistor is required, if not). Higher FRHP (= lower inductance) allows a higher crossover frequency and is always preferred when using a smaller value output capacitor. The inductance value can be selected to set the inductor current ripple between 30% and 70% of the average inductor current as a good compromise between RR, FRHP, and inductor falling slope. In this example, 60% ripple ratio (RR = 0.6) is selected as the maximum inductor current ripple ratio (the inductor current ripple ratio is the biggest when D = 0.33). The target inductance value is calculated using Equation 20: LM TARGET 0.14 u RLOAD RR u FSW VLOAD LM GUIDE 9.5 2.6 0.6 u 440 k VSUPPLY 0.14 u MIN 1.94 P >H@ u VSUPPLY FSW u VLOAD u ILOAD MIN (20) 9.5 2.5 u 2.5 440 k u 9.5 u 2.6 1.61 P >H@ (21) If the target inductance is smaller than the value calculated using Equation 20, consider adding the slope compensation resistor (RSL), as mentioned in Section 9.2.2.6, or select a smaller RR and recalculate the inductance using Equation 21. A standard value of 2.2 µH is chosen for LM. The required inductor saturation current rating is estimated after selecting RS and RSL. 9.2.2.5 Current Sense (RS) Based on the assumptions that 20% of current limit margin (MCL = 1.2), 80% estimated efficiency (Eff = 0.8) at full load and no RSL populated, RS is calculated using Equation 22 and Equation 23. 26 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 FSW_RT (VVOUT - VVIN ) - 10 ´ 30μA ´ (2kΩ + RSL ) ´ ´D VVOUT -REG FSYNC RS = [ W] 1 ö æ VSUPPLY(MIN) ´ D ´ ç V FSYNC ÷ 1 LOAD ´ ILOAD ÷ ´ MCL 10 ´ ç + ´ LM ç VSUPPLY(MIN) ´ Eff 2 ÷ ç ÷ è ø 1.2 + 0.6 ´ 1.2 0.6 u RS 9.5 2.5 9.5 § ¨ 9.5 u 2.6 10 u ¨ ¨ 2.5 u 0.8 ¨ © 2.5 · § 10 u 30 P u 2 k 0 u 1u ¨ 1 ¸ © 9.5 0.7 ¹ 2.5 · 1 · § 2.5 u ¨ 1 u ¸ ¸ 1 © 9.5 0.7 ¹ 440 k ¸ u 1.3 u 2 2.2 u ¸ ¸ ¹ (22) 7.44 m >:@ (23) Substitute FSW_RT for FSYNC if clock synchronization is not used. A standard value of 7 mΩ is chosen for RS. A low-ESL resistor is recommended to minimize the error caused by the ESL. 9.2.2.6 Slope Compensation Ramp (RSL) The minimum inductance value, which can prevent subharmonic oscillation without RSL, is calculated using Equation 24. If the selected inductance value is less than the minimum inductance calculated using Equation 24, add a slope compensation resistor (RSL) externally. LM MIN 0.5 u VLOAD VF VSUPPLY MIN 60 m u FSW u RS u Margin 0.5 u 9.5 0.7 2.5 60 m u 440 k u 7 m u 1.2 1.22 P >H@ (24) 1.2 is the recommended margin to cover non-ideal factors. If needed, use Equation 25 to find the RSL value which matches the typical amount of slope compensation. RSL = 0.82 ´ (VLOAD + VF ) - VSUPPLY(MIN) LM ´ FSW ´ 30mA ´ RS - 2k[W] (25) In this example, RSL is not populated because the selected inductance value, 2.2 µH, is greater than the minimum required inductance from Equation 24. After selecting RS and RSL, the peak inductor current at current limit (IPEAK-CL) can be calculated. Setting the inductor saturation current rating higher than the IPEAK-CL is recommended. VCL - 10 ´ 30mA ´ (2kW + RSL ) ´ IPEAK -CL = FSYNC 10 ´ RS 1.2 0.6 u IPEAK FSW_RT 9.5 2.5 9.5 CL ´D + VSUPPLY(MIN) LM 2.5 · § 10 u 30 P u 2 k u 1u ¨ 1 ¸ © 9.5 0.7 ¹ 10 u 7 m ´ TD [A] (26) 2.5 u 20 n 17.0 > A @ 2.2 u (27) TD is the typical propagation delay of current limit. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 27 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9.2.2.7 Output Capacitor (COUT) There are a few ways to select the proper value of output capacitor (COUT). The output capacitor value can be selected based on output voltage ripple, output overshoot, or output undershoot due to load transient. In this example, COUT is selected based on output undershoot because the wake-up performance is similar with no-load to full-load transient performance. The output undershoot becomes smaller by increasing FCROSS or by decreasing FLP. A smaller COUT is allowed by increasing FCROSS or by decreasing FLP. To increase FCROSS, FSW and FRHP must be increased because the maximum FCROSS is, in general, limited at 1/10 of FRHP at VSUPPLY(MIN) or 1/10 of FSW, whichever is lower. FRHP is calculated using Equation 28. FRHP § VSUPPLY MIN RLOAD u ¨ ¨ © VLOAD VF 2S u LM · ¸ ¸ ¹ 2 9.5 § 2.5 · u 2.6 ©¨ 9.5 0.7 ¹¸ 2S u 2.2 u 2 15.9 k >HZ @ (28) FCROSS is selected at 1/10 of FRHP or 1/10 of FSW, whichever is lower. FRHP 10 1.59 k >HZ @ FSW 10 440 k 10 (29) 44 k >Hz@ (30) In this example, 1.59 kHz is selected as a target FCROSS and FLP is selected to be 286 Hz (K1 = 0.18). In general, there is about 5% or less undershoot with FLP = 0.1 × FCROSS (K1 = 0.1) and 10% or less undershoot with FLP = 0.2 × FCROSS (K1 = 0.2) during 0% to 100% load transient. The recommended K1 factor range is from 0.02 to 0.2. FLP is calculated using Equation 31. FLP = 2 2p ´ RLOAD ´ COUT [Hz] (31) The minimum required output capacitance value is calculated using Equation 32. COUT 2 2S u RLOAD u FLP 2 9.5 u 286 2S u 2.6 304 P >F@ (32) The maximum output ripple current is calculated at the minimum input supply voltage using Equation 33: IRIPPLE _ COUT MAX VLOAD u ILOAD 2 u VSUPPLY MIN 9.5 u 2.6 2 u 2.5 4.9 > A @ (33) The ripple current rating of the output capacitors must be enough to handle the output ripple current. By using multiple output capacitors, the ripple current can be split. In practice, ceramic capacitors are placed closer to the diode and the MOSFET than the bulk aluminum capacitors to absorb the majority of the ripple current. In this example, three 100-µF capacitors are placed in parallel to ensure ripple current capability. If high-ESR capacitors are used for the output capacitor, additional 10-µF ceramic capacitors can be placed close to the switching components to minimize switching noise. 28 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9.2.2.8 Loop Compensation Component Selection and Maximum ESR Based on Equation 18, CCOMP is calculated using Equation 34 and Equation 35: 2 CCOMP (over CCOMP damping) = [AM ´ AFB ]2 - 1 2p ´ RO ´ FCROSS = é RLOAD D ' ù 1.2 ´ ´ ´ RO ´ Gm ú - 1 ê ë RS ´ 10 2 VLOAD û 2p ´ RO ´ FCROSS 2.5 ª 9.5 º « 2.6 » 1.2 9.5 0.7 u u u 10 M u 2 m» « 2 9.5 « 7 m u 10 » ¬ ¼ 2S u 10 M u 1.59 k over damping (34) 2 1 162 n[F] (35) By selecting CCOMP following Equation 34, the typical phase margin is set to 90⁰ and the loop response is overdamped. In this example, FZ_EA is placed at a frequency 3 times higher than the FLP to have lower phase margin but faster settling time (K2 = 3, target FZ_EA is 860 Hz). The recommended range of FZ_EA is from 1 × FLP to 4 × FLP (1 ≤ K2 ≤ 4). Practical crossover frequency will vary with K2 with a range of 0.5 × FCROSS to 1.0 × FCROSS. CCOMP CCOMP over damping K2 162 n 3 54 n >F@ (36) A standard value of 56 nF is chosen for CCOMP. RCOMP is selected to set the error amplifier zero at 860 Hz. RCOMP 1 2S u CCOMP u FZ _ EA 1 2S u 56 n u 860 3.31k >: @ (37) A standard value of 3.32 kΩ is chosen for RCOMP. CHF is usually used to create a pole at high frequency (FP_EA) to cancel FZ_ESR. By using a small ESR capacitor that can place FZ_ESR greater than 10 × FCROSS, the output capacitor ESR would not affect the loop stability. The maximum ESR which does not affect the loop response is calculated using Equation 38. RESR MAX 1 2S u COUT u FCROSS u 10 1 2S u 330 u u 1.59 k u 10 30 m >: @ (38) 9.2.2.9 PVCC Capacitor, AVCC Capacitor, and AVCC Resistor The PVCC capacitor supplies the peak transient current to the LO driver. The value of PVCC capacitor (CPVCC) must be 4.7 μF or higher and must be a high-quality, low-ESR, ceramic capacitor. CPVCC must be placed close to the PVCC pin and the PGND pin. A value of 4.7 μF is selected for this design example. The AVCC capacitor must be placed close to the device. The recommended AVCC capacitor value is 0.1 μF. The AVCC resistor should be placed between PVCC and AVCC pins. The recommended AVCC resistor value is 10 Ω. 9.2.2.10 VOUT Filter (CVOUT, RVOUT) The VOUT pin is the input of the internal VCC regulator and also is the input of the output voltage sensing. To minimize noise at the VOUT pin, a 1-μF capacitor must be placed at the VOUT pin in most cases. If multiple output capacitors are used, one of them can be placed at the VOUT pin as CVOUT. The VOUT capacitor must be a high-quality, low-ESR, ceramic capacitor and must be placed close to the device. A resistor can be added at the VOUT pin (RVOUT) to form a RC filter (see Figure 9-3). In this case, the maximum resistor value should be less than or equal to 2 Ω. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 29 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9.2.2.11 Input Capacitor The input capacitors reduce the input voltage ripple. Assuming high-quality ceramic capacitors are used for the input capacitors, the maximum input voltage ripple can be calculated using Equation 39. VRIPPLY(CIN) = VLOAD 32 ´ LM ´ CIN ´ FSW 2 [V] (39) The required input capacitor value is a function of the impedance of the source power supply. More input capacitors are required if the impedance of the source power supply is not low enough. In the example, three 10-µF ceramic capacitors are used. 9.2.2.12 MOSFET Selection The MOSFET gate driver of the LM51501-Q1 is powered by the internal 5-V VCC regulator. The MOSFET driven by the LM51501-Q1 must have a logic-level gate threshold with its on-resistance specified at 4.5 V or lower and must be rated to handle the maximum output voltage plus any switch node ringing. The maximum gate charge is limited by the 75-mA PVCC sourcing current limit, and is calculated in Equation 40: QG(@5V) < 75m [C] FSW (40) A leadless package is preferred for high switching-frequency designs. The MOSFET gate capacitance should be small enough so that the gate voltage is fully discharged during the off-time. 9.2.2.13 Diode Selection A Schottky is the preferred type for D1 diode due to its low forward voltage drop and small reverse recovery charge. Low reverse leakage current is an important parameter when selecting the Schottky diode. The diode must be rated to handle the maximum output voltage plus any switching node ringing. Also, it must be able to handle the average output current. To prevent chatter between wake-up and standby, the forward voltage drop of the D1 diode must be less than 0.95 V at full load. 9.2.2.14 Efficiency Estimation The total loss of the boost converter (PTOTAL) can be expressed as the sum of the losses in the LM51501-Q1 (PIC), MOSFET power losses (PQ), diode power losses (PD), inductor power losses (PL), and the loss in the sense resistor (PRS). PTOTAL = PIC + PQ + PD + PL + PRS [W] (41) PIC can be separated into gate driving loss (PG) and the losses caused by quiescent current (PIQ) in Equation 42. PIC = PG + PIQ [W] (42) Each power loss is approximately calculated in Equation 43 and Equation 44: PG = QG(@5V) ´ VVOUT ´ FSW [W] (43) PIQ = VVOUT ´ IVOUT + VVIN ´ IVIN [W] (44) IVIN and IVOUT values in each mode can be found in the supply current section of Section 7.5. PQ can be separated into switching loss (PQ(SW)) and conduction loss (PQ(COND)) in Equation 45. PQ = PQ(SW) + PQ(COND) [W] 30 Submit Document Feedback (45) Copyright © 2021 Texas Instruments Incorporated www.ti.com LM51501-Q1 SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 Each power loss is approximately calculated using Equation 46: PQ(SW) = 0.5 ´ (VVOUT + VF )´ ISUPPLY ´ (tR + tF )´ FSW [W] (46) tR and tF are the rise and fall times of the low-side N-channel MOSFET device. ISUPPLY is the input supply current of the boost converter. PQ(COND) = D ´ ISUPPLY 2 ´ RDS(ON) [W] (47) RDS(ON) is the on-resistance of the MOSFET and is specified in the MOSFET data sheet. Consider the RDS(ON) increase due to self-heating. PD can be separated into diode conduction loss (PVF) and reverse recovery loss (PRR) in Equation 48. PD = PVF + PRR [W] (48) Each power loss is approximately calculated using Equation 49 and Equation 50: PVF = (1 - D) ´ VF ´ ISUPPLY [W] (49) PRR = VLOAD ´ QRR ´ FSW [W] (50) QRR is the reverse recovery charge of the diode and is specified in the diode data sheet. Remember that reverse recovery characteristics of the diode strongly affect efficiency, especially when the output voltage is high. PL is the sum of DCR loss (PDCR) and AC core loss (PAC) in Equation 51. DCR is the DC resistance of inductor and is mentioned in the inductor data sheet. PL = PDCR + PAC [W] (51) Each power loss is approximately calculated by Equation 52, Equation 53, and Equation 54: PDCR = ISUPPLY 2 ´ RDCR [W] Copyright © 2021 Texas Instruments Incorporated (52) Submit Document Feedback 31 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 PAC = K ´ DIbFSW a [W] (53) where • • ∆I is the peak-to-peak inductor current ripple. K, α, and β are core dependent factors that can be provided by the inductor manufacturer. VSUPPLY ´ D ´ DI = 1 FSYNC LM (54) PRS is calculated as Equation 55: PRS = D ´ ISUPPLY 2 ´ RS [W] (55) Efficiency of the power converter can be estimated using Equation 56: Efficiency = VLOAD ´ ILOAD ´ 100[%] PTOTAL + VLOAD ´ ILOAD (56) 9.2.3 Application Curves 200 µs/DIV Figure 9-4. Automatic Wake-Up 32 Submit Document Feedback 2.6 A to 1.3 A, 0.1 V/DIV, and 2 ms/DIV Figure 9-5. Load Transient Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9.3 System Examples 9.3.1 Lower Standby Threshold in SS Configuration By connecting the VIN pin to the VOUT pin, the current limit threshold at the current limit comparator input (VCL) is set to 1.2 V. In SS configuration, the VOUT standby threshold is ignored. The device goes into the standby mode when VOUT > VIN standby threshold. VSUPPLY VLOAD VOUT VIN LO CS AGND & PGND VOUT EN STATUS LM51501 SYNC COMP RT VSET PVCC AVCC Figure 9-6. Lower Standby Threshold in SS Configuration 9.3.2 Dithering Using Dither Enabled Device Dithering is achieved by connecting DITH output to the RT pin through a resistor. LM5141 LM51501 RT DITH Figure 9-7. Dithering Using the Dither-Enabled Device LM5141 9.3.3 Clock Synchronization With LM5140 Clock synchronization can be achieved by connecting LM5140's SYNCOUT to SYNC. LM5140 LM51501 SYNOUT SYNC Figure 9-8. Clock Synchronization With LM5140 Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 33 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 9.3.4 Dynamic Frequency Change Switching frequency can be changed dynamically during operation by changing the RT resistor. LM51501 RT Low Fsw/ Hi Fsw Figure 9-9. Dynamic Frequency Change 9.3.5 Dithering Using an External Clock If a low-frequency clock is available, dithering can be achieved by injecting a ramp signal into RT. LM51501 RT Figure 9-10. Dithering Using an External Clock 34 Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated www.ti.com LM51501-Q1 SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 10 Power Supply Recommendations The LM51501-Q1 is designed to operate from a power supply or battery with a voltage range of 1.5 V to 42 V. The input power supply should be able to supply the maximum boost supply voltage and handle the maximum input current at 1.5 V. The impedance of the power supply and battery, including cables, must be low enough that an input current transient does not cause an excessive drop. Additional input ceramic capacitors can be required at the supply input of the converter. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 35 LM51501-Q1 SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 www.ti.com 11 Layout 11.1 Layout Guidelines The performance of switching converters heavily depends on the quality of the PCB layout. The following guidelines will help users design a PCB with the best power conversion performance, thermal performance, and minimize generation of unwanted EMI. • • • • • • • • • • • • • 36 Place Q1, D1, and RS first. Place ceramic COUT and make the switching loop (COUT-D1-Q1-RS-COUT) as small as possible. Leave copper area next to D1 for thermal dissipation. Place LM51501-Q1 close to RS. Place CPVCC as close to the device as possible between PVCC and PGND. Connect PGND directly to the center of the sense resistor using a wide and short trace. Connect CS to the center of the sense resistor. Connect through vias if required. Connect filter capacitor between CS pin and exposed pad. Connect AGND directly to the analog ground plain and connect to RSET, RT, and CCOMP. Connect the exposed pad to the analog ground plain and the power ground plain through vias. Connect LO directly to the gate of Q1. Make the switching signal loop (LO-Q1-RS-PGND-LO) as small as possible. Place CVOUT as close to the device as possible. The LM51501-Q1 has an exposed thermal pad to aid power dissipation. Adding several vias under the exposed pad helps conduct heat away from the device. Connect the vias to a large ground plane on the bottom layer. Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 11.2 Layout Example Figure 11-1. LM51501-Q1 PCB Layout Example Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 37 LM51501-Q1 www.ti.com SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 12 Device and Documentation Support 12.1 Device Support 12.1.1 Third-Party Products Disclaimer TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE. 12.1.2 Development Support 12.1.2.1 Custom Design With WEBENCH® Tools Click here to create a custom design using the LM51501-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. 12.2 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. 12.3 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. 12.4 Trademarks TI E2E™ is a trademark of Texas Instruments. WEBENCH® is a registered trademark of Texas Instruments. is a registered trademark of Texas Instruments. All trademarks are the property of their respective owners. 12.5 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. 12.6 Glossary TI Glossary 38 This glossary lists and explains terms, acronyms, and definitions. Submit Document Feedback Copyright © 2021 Texas Instruments Incorporated www.ti.com LM51501-Q1 SNVSAZ0C – MARCH 2018 – REVISED OCTOBER 2021 13 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. Copyright © 2021 Texas Instruments Incorporated Submit Document Feedback 39 PACKAGE OPTION ADDENDUM www.ti.com 23-Jun-2023 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) Samples (4/5) (6) LM51501QRUMRQ1 ACTIVE WQFN RUM 16 2000 RoHS & Green SN Level-2-260C-1 YEAR -40 to 125 LM 51501Q Samples LM51501QRUMTQ1 ACTIVE WQFN RUM 16 250 RoHS & Green SN Level-2-260C-1 YEAR -40 to 125 LM 51501Q Samples LM51501QURUMRQ1 ACTIVE WQFN RUM 16 2000 RoHS & Green SN Level-2-260C-1 YEAR -40 to 150 LM 51501QU Samples LM51501QWRUMRQ1 ACTIVE WQFN RUM 16 3000 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 125 LM 51501QW Samples LM51501QWRUMTQ1 ACTIVE WQFN RUM 16 250 RoHS & Green NIPDAU Level-2-260C-1 YEAR -40 to 125 LM 51501QW Samples (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